TECHNICAL BACKGROUND Ethylene (co) polymers, which contain groups derived from vinylsilanes, are used commercially for many purposes, for example for electrical wire coating (jacketing and/or insulation layer (s) ) of various types, pipes, adhe- sives, gasketing, and crosslinked foams. In many of these applications the silicon atom has attached to it one or more groups which can hydrolyze and then react to form a crosslinked polymer or a covalent bond to a surface.

Generally speaking the vinylsilane groups are"attached"to the ethyl- ene polymers by one of two methods. In the first method ethylene and the vinylsilane are copolymerized at high temperature and pressures, often in the presence of a free radical generator to form a copolymer. See for instance US3225018, which is incorporated by reference herein for all purposes as if fully set forth. Some of the repeat units derived from the vinylsilane in such a copolymer are wherein Si= is a silyl group, and most of the rest are present as ends of chains or there are typically 2 or 4 or more methylene groups between the silicon atom and the methine carbon atom. Since this polymerization process is very similar to the so-called high pressure homopolymerization of ethylene, these copolymers have structures similar to low density polyethylene (LDPE).

For an analysis of branching in LDPE, see Usami, et al., Macromolecules, vol.

17, p. 1756 etseq., (1984).

The other method of making ethylene polymers is to graft an allyl-or vinylsilane onto a preexisting polyethylene (PE). See for instance US3646155, which is also incorporated by reference herein for at ! purposes

as if fully set forth. Grafting has the advantage that any type of PE, such as LDPE or high density polyethylene (HDPE) may be grafted. The disadvan- tage is that the grafting step requires the use of free radical catalysts, and is an extra step in the manufacturing process of the vinylsilane containing PE.

Too little free radical catalysis and the vinylsilane is not grafted or only partly grafted, while too much free radical catalysis can result in crosslinking of the PE by conventional free radical methods. The grafted vinylsilane is usually considered to be present as a side chain on the PE having the formula- CH2CH2Si- (XIV), where the free bond to the carbon atom is the attachment point to a carbon atom of the PE chain. Similarly, one would expect that grafted allylsilanes would be present as a side chain of the formula- CH2CH2CH2Si= (XIX).

PEs containing attached vinylsilanes are particularly useful because they are thermoplastics which may be formed by normal thermoplastic proc- essing techniques until they are exposed to water, and usually also one or both of heat and catalysts for the crosslinking reactions (see for instance pre- viously incorporated US3646155 and US3225018). Once they are crosslinked they typically behave as thermbset materials. More importantly certain properties, such as resistance to treeing (failure brought on by expo- sure to high voltage electrical fields), and/or stress crack resistance, and/or creep resistance, are usually improved. Thus new methods of preparing allyl- or vinylsilane containing polyolefins, especially polyethylenes, and new vinyl- silane containing polyolefin compositions, are constantly being sought.

SUMMARY OF THE INVENTION This invention concerns a process for the copolymerization of one or more hydrocarbon olefins and one or both of an allylsilane and a vinylsilane, comprising the step of contacting, under coordination polymerizing conditions: a monomer mixture comprising ethylene or an a-olefin of the formula H2C=CH (CH2) tCH3 wherein t is 0 or an integer of 1 to 20, and one or both of an allylsilane and a vinylsilane and optionally one or more other copolymeri- zable olefins ; and

an active polymerization catalyst comprising a transition metal complex comprising a Group 8,9, 10 or 11 (IUPAC notation) transition metal.

This invention also concerns a first copolymer comprising repeat units derived from ethylene and one or both of an allylsilane and a vinylsilane, said copolymer having a density of 0.92 g/cc or more.

Also described herein is a second copolymer comprising repeat units derived from ethylene and one or both of an allylsilane and a vinylsilane, said copolymer having at least about 10 alkyl branches per 1000 methylene groups, wherein at least about 10 percent of said alkyl branches are methyl branches.

Similarly described is a third copolymer comprising repeat units derived from ethylene and one or both of an allylsilane and a vinyisilane, said copoly- mer having at least 2 methyl branches per 1000 methylene groups.

Also described is a fourth copolymer comprising repeat units derived from ethylene and one or both of an allylsilane and a vinylsilane, said copoly- mer having a melting point of about 115°C or higher.

Also described is a fifth copolymer comprising repeat units derived from ethylene and a vinylsilane, said copolymer containing the group wherein represents the rest of the polymer (chain), and Si_ is a silyl group. Note that this structure throughout this application is not meant to im- ply whether the olefinic bond is cis or trans.

Also described herein is a sixth copolymer of ethyiene, one or both of an allylsilane and a vinylsilane, and optionally other copolymerizable mono- mers, containing at least 1.0 or more mole percent (total) of incorporated allyl- silane and (plus) vinylsilane.

Also described herein is a copolymer comprising repeat units derived from ethylene and a vinylsilane, said copolymer containing the group

whereir represents the rest of the polymer chain, and Sis is a silyl group.

Described herein is a copolymer comprising repeat units derived from one or more hydrocarbon olefins and a vinylsilane, said copolymer having at least about 30 alkyl branches per 1000 methylene groups, and there are also at least about 10 methyl branches per 1000 methylene groups present..

Herein is disclosed a first polyolefin containing a copolymerized olefinic silane containing the repeat unit

wherein at least about 5 mole percent of the silicon atoms in said polymer are in a repeat unit (XVI) in which n is 1, and at least about 5 mole percent of the silicon atoms in said polymer are in a repeat unit (XVI) in which n is 3, wherein said percentage is based on all the silicon atoms in said polymer except those in olefinic silicon containing end groups.

Also disclosed herein is a second polyolefin containing a copolymer- ized olefinic silane containing the repeat unit

wherein at least about 5 mole percent of the silicon atoms in said polymer are in a repeat unit (XVI) in which n is 1, and at least about 5 mole percent of the silicon atoms in said polymer are in a repeat unit (XVI) in which n is 0, wherein said percentage is based on all the silicon atoms in said polymer except those in olefinic silicon containing end groups.

Also disclosed herein is a third polyolefin containing a copolymerized olefinic silane containing the repeat unit

wherein at least about 70 mole percent of the silicon atoms in said polymer are in a repeat unit (XVI) in which n is 0, wherein said percentage is based on all the silicon atoms in said polymer except those in olefinic silicon containing end groups.

These and other features and advantages of the present invention will be more readily understood by those of ordinary skill in the art from a reading of the following detailed description. It is to be appreciated that certain fea- tures of the invention which are, for clarity, described below in the context of separate embodiments, may also be provided in combination in a single em- bodiment. Conversely, various features of the invention which are, for brevity, described in the context of a single embodiment, may also be provided sepa- rately or in any subcombination.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows the 1H NMR spectrum of a typical ethyl- ene/vinyltriethoxysilane copolymer of the invention, with assignments of some of the peaks in the spectrum.

Figure 2 shows the 13C NMR spectrum of the polymer of Example 34, and some of the assignments of the peaks.

Figure 3 shows the 13C NMR spectrum of the polymer of Example 361, and some of the assignments of the peaks.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Herein certain terms are used, and some of them are: A"hydrocarbyl group"is a univalent group containing only carbon and hydrogen. If not otherwise stated, it is preferred that hydrocarbyl groups herein preferably contain 1 to about 30 carbon atoms.

By"substituted hydrocarbyl"herein is meant a hydrocarbyl group that contains one or more substituent groups which are inert under the process conditions to which the compound containing these groups is subjected (e. g.,

an inert functional group, see below). The substituent groups also do not substantially detrimentally interfere with the polymerization process or opera- tion of the polymerization catalyst system. If not otherwise stated, it is pre- ferred that substituted hydrocarbyl groups herein contain 1 to about 30 carbon atoms. Included in the meaning of"substituted"are chains or rings containing one or more heteroatoms, such as nitrogen, oxygen and/or sulfur, and the free valence of the substituted hydrocarbyl may be to the heteroatom. In a substituted hydrocarbyl, all of the hydrogens may be substituted, as in trifluo- romethyl.

By" (inert) functional group"herein is meant a group other than hydro- carbyl or substituted hydrocarbyl which is inert under the process conditions to which the compound containing the group is subjected. The functional groups also do not substantially interfere with any process described herein that the compound in which they are present may take part in. Examples of functional groups include halo (fluoro, chloro, bromo and iodo), ether such as -oR25,-CO2R22,-NO2, and-NR222, wherein each R22 is independently hydro- carbyl or substituted hydrocarbyl. In cases in which the functional group may be near a transition metal atom the functional group should not coordinate to the metal atom more strongly than the groups in compounds which are shown as coordinating to the metal atom, that is they should not displace the desired coordinating group.

By a"cocatalyst"or catalyst activator"is meant a compound that re- acts with a transition metal compound to form an activated catalyst species.

One such catalyst activator is an"alkyl aluminum compound"which, herein, is meant a compound in which at least one alkyl group is bound to an aluminum atom. Other groups such as, for example, alkoxide, hydride, bridging oxygen atom, and halogen may also be bound to aluminum atoms in the compound.

By relatively noncoordinating (or weakly coordinating) anions are meant those anions as are generally referred to in the art in this manner, and the coordinating ability of such anions is known and has been discussed in the literature, see for instance W. Beck. , et al., Chem. Rev., vol. 88 p. 1405- 1421 (1988), S. H. Strauss, Chem. Rev., vol. 93, p. 927-942 (1993), and E. Y. -X. Chen, et al., Chem. Rev., vol. 100, p. 1391-143 (2000), all of which are hereby included by reference. Among such anions are those formed from

the aluminum compounds in the immediately preceding paragraph and X-in- cluding R93AIX-, R92AICIX, R9AICI2X, and"R9AIOX", wherein R9 is alkyl and X is an anion abstracted from the transition metal, such as halide or methyl.

Other useful noncoordinating anions include BAF- {BAF = tetrakis [3,5- bis (trifluoromethyl) phenyl] borate}, SbF6-, PF6-, and BF4-, trifluoromethanesul- fonate, p-toluenesulfonate, (RfS02) 2N-, and (C6F5) 4B-.

By"aryl"is meant a monovalent aromatic group in which the free va- lence is to the carbon atom of an aromatic ring. An aryl may have one or more aromatic rings which may be fused, connected by single bonds or other groups, such as 9-anthracenyl or 1-naphthyl. Unless otherwise stated aryl groups preferably contain 5 to 30 carbon atoms.

By"substituted aryl"is meant a monovalent aromatic group substituted as set forth in the above definition of"substituted hydrocarbyl". Suitable sub- stituents include alkyl, aryl such as phenyl, halo, alkoxy, ester, dialkylamino and nitro. Similar to an aryl, a substituted aryl may have one or more aro- matic rings which may be fused, connected by single bonds or other groups; however, when the substituted aryl has a heteroaromatic ring, the free va- lence in the substituted aryl group can be to a heteroatom (such as nitrogen) of the heteroaromatic ring instead of a carbon. Unless otherwise stated, sub- stituted aryl groups contain 5 to about 30 carbon atoms.

By a"monoanionic ligand"is meant a ligand with one negative charge.

By a"neutral ligand"is meant a ligand that is not charged.

"Alkyl group"and"substituted alkyl group"have their usual meaning (see above for substituted under substituted hydrocarbyl). Unless otherwise stated, alkyl groups and substituted alkyl groups preferably have 1 to about 30 carbon atoms.

By a"norbornene-type monomer"is meant ethyliden norbornene, di- cyclopentadiene, or a compound of the formula (VI)

wherein m'is an integer from 0 to 5, and each of R71 to R74 independently rep- resents a hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group. The norbornene may be also substituted by one or more hydrocarbyl, substituted hydrocarbyl or functional groups in other positions, with the ex- ception of the vinylic hydrogens, which remain. Two or more of R71 to R74 may also be taken together to form a cyclic group. Norbornene (itself), di- methyl endo-norbornene-2, 3-dicarboxylate, t-butyl 5-norbornene-2- carboxylate are preferred norbornenes and norbornene (itself) is especially preferred. Another type of preferred norbornene contains fluorinated al- kyl (ene) groups.

By a"vinylsilane"is meant a compound in which at least one vinyl group (-CH=CH2) is bonded directly to a silicon atom. Other groups may also be bonded to the silicon atom (s) present, and the compound may contain more than one silicon atom.

By an"allylsilane"is meant a compound in which at least one allyl group (-CH2CH=CH2) is bonded directly to a silicon atom. Other groups may also be bonded to the silicon atom (s) present, and the compound may contain more than one silicon atom.

By an"alkyl branch"is meant a branch which is an alkyl group, and does not for instance contain a silicon or any other heteroatom (atoms other than carbon and hydrogen).

By a"bidentate ligand"herein is meant a ligand that has at least two heteroatoms (or heteroatom containing groups) and which are in mutual posi- tions where they may potentially coordinate to the transition metal. Such het- eroatoms include O, S, N, P and Se, and the heteroatoms may be independ- ently selected. Alternatively one or both of the coordination sites in a biden- tate ligand may have a carbon atom present.

By a"tridentate ligand"herein is meant a ligand that has at least three heteroatoms (or heteroatom containing groups) which are in mutual positions where they may potentially coordinate to the transition metal. Such heteroa- toms include O, S, N, P and Se, and the heteroatoms may be independently selected. Alternatively one or more of the coordinating atoms in a tridentate ligand may be carbon atoms.

By a"heteroatom connected monovalent radical"is meant a substituted hydrocarbyl which is a monovalent radical or group which is connected to the rest of the compound through a valence of a heteroatom (an atom other than C and H). The group may be more than monovalent if it is part of a ring con- nected by a bridging group.

By"under coordination polymerization conditions"is meant the condi- tions for a coordination polymerization that are usually used for the particular polymerization catalyst system being used (except as otherwise indicated herein). These conditions include things such as pressure, temperature, catalyst and catalyst (if present) concentrations, the type of process such as batch, semibatch, continuous, gas phase, solution or liquid slurry etc., ex- cept as modified by conditions specified or suggested herein. Conditions normally done or used with the particular polymerization catalyst system, such as the use of hydrogen for polymer molecular weight control, are also consid- ered"under polymerization conditions". Other polymerization conditions such as the presence of other polymerization catalysts, etc. , are applicable with this polymerization process and may be found in the references cited herein.

By"Es"is meant a parameter to quantify steric effects of various groupings, see R. W. Taft, Jr. , J. Am. Chem. Soc., vol. 74, p. 3120-3128 (1952), and M. S. Newman, Steric Effects in Organic Chemistry, John Wiley & Sons, New York, 1956, p. 598-603, which are both hereby included by refer- ence. For the purposes herein, the Es values are those described for o- substituted benzoates in these publications. If the value of Es for a particular group is not known, it can be determined by methods described in these ref- erences.

By a"polyolefin containing a copolymerized olefinic silane"is meant a polymer comprising repeat units derived from a hydrocarbon olefin (an olefin containing only carbon or hydrogen) and an olefinic silane, that is an olefin containing a silyl group. Such olefinic silanes include vinylsilanes, allylsilanes and alkenylsilanes. Preferably the hydrocarbon olefin is ethylene and/or an a- olefin of the formula H2C=CH (CH2) tCH3 wherein t is 0 or an integer of 1 to 20, and more preferably the hydrocarbon olefin is ethylene. The choice of t being an integer of 1 to 20 does not preclude the presence of spontaneous long

chain branching in the resulting polymers. Other copolymerizable olefins may be present (in copolymers with alkenylsilanes, allylsilanes and/or vinylsilanes), such as acrylate esters, esters of the formula H2C=CHR5CO2R'6 wherein R75 is alkylen, preferably n-alkylene, and R76 is hydrocarbyl or substituted hydro- carbyl, and vinyl ketones. Other useful hydrocarbon olefins include norbor- nene, and cyclopentene. Another type of olefin is a fluorinated olefin, par- ticularly a fluorinated olefin which have no vinylic fluorine atoms. A particu- larly useful type of such fluorinated monomer has the formula H2C=CH (CH2) a (CF2) bF wherein a is an integer of 2 to 20 and b is an integer of 1 to 20. When fluorinated monomers are included within the polymer pro- duced, the surface properties of the polymer may be modified, for instance hydrophilicity and/or lipophilicity. It will be understood that not all types of transition metal complexes will copolymerize some or all of the above co- monomers. References to these complexes as polymerization catalysts, as for instance cited herein, often have information on what comonomers can be copolymerized by these complexes. Another copolymerizable monomer which may be present is carbon monoxide.

In the context of the present invention, the use of"a"or"an"refers to one or more unless otherwise specifically stated. For example,"a vinylsilane" or"an allylsilane"refers to one or more vinylsilanes or allylsilanes respec- tively.

Also in the context of the present invention, the use of"comprising"is open-ended as in its normal meaning, unless otherwise specifically stated.

For example, "a monomer mixture comprising ethylene and a vinylsilane"may also include one or more other copolymerizable monomers, as discussed further below. As another example, "an active polymerization catalyst com- prising a transition metal complex"may include the complex itself if such complex is in and of itself an active polymerization catalyst, or may also in- clude one or more cocatalysts as required to activate such complex.

The polymerization catalyst systems used herein include a Group 8,9, 10 or 11 transition metal. In one preferred variation with a Group 8,9, 10, or 11 transition metal complex the transition metal atom is coordinated to a bidentate ligand. In another preferred variation with a Group 8 or 9 transition metal, the transition metal is complexed with a tridentate ligand. When the

complex contains a bidentate ligand (other than including acetonylacetonate, s-allyl or s-benzyl groups) preferred transition metals are Ni, Fe, Cu and Pd, Pd and Ni are very preferred, and Ni is especially preferred. When the com- plex contains a tridentate ligand, preferred transition metals are Fe and Co, and Fe is especially preferred.

The present invention concerns the copolymerization of olefins with one or both of allylsilanes and vinylsilanes. Vinylsilanes are preferred.

Generally vinylsilanes (and to a lesser extent allylsilanes) may become parts of a polymer by either being copolymerized or being grafted onto a , polymer. Herein the word"copolymerized"means the silane is a monomer that is copolymerized into the polymer when the polymer is originally formed from its constituent monomers. Herein the product of this polymerization is referred to as a copolymer. When the silane is attached to an already formed polymer, most commonly by using free radically catalyzed reactions, the polymer is referred to herein as a graft or grafted polymer. This grafted poly- mer may itself be a copolymer (formed originally from two or more mono- mers), but the allyl-or vinylsilane attached to the polymer did not become at- tached to the polymer until after the polymer was formed.

Bidentate ligands suitable for the nickel and palladium complexes in- clude neutral and monoanionic ligands. Examples of suitable neutral ligands, transition metal complexes thereof, methods of making such ligands and complexes and active polymerization catalysts, and polymerization processes involving the same, are described in US-A-2001025244, US5714556, US5852145, US5880241, US5955555, US6030917, US6034240, US6090900, US6103658, US6232259, US6200925, US6242377, US6262194, US6372682, JP-A-09025713, JP-A-11158213, JP-A-11158214, W09847934, W09849208, W00006620, W00018776, W00020377, WO0021971, W00050470, W00050474, W00059956, W00059961, W00068280, W00110876, W00125298, W00142257, W00174743, W00174831, W00187996, W00216033, and U. S. Provisional Application Se- rial No. 60/294,794 (filed May 31,2001), all of which are hereby incorporated by reference herein for all purposes as if fully set forth.

Examples of suitable monoanionic ligands, transition metal complexes thereof, methods of making such ligands and complexes and active polymer- zation catalysts, and polymerization processes involving the same, are de- scribed in US6057466, US6060569, US6174975, US6174976, US6184428, US6245871, US6242623, W00020377, W00056785, W00059956, WO0119786, WO0130865, WO0172854, WO0144324, WO0144325, WO0183571, WO0192347, W00208236, EP-A-0950667, EP-A-1101768, JP- A-11199592, JP-A-11199593, JP-A-2000086677, JP-A-2000028170, U. S.

Patent Application Serial No. 09/871,099 (filed May 31,2001), U. S. Patent Application Serial No. 09/871,100 (filed May 31,2001), and U. S. Provisional Application Serial No. 60/308,974 (filed July 31,2001), all of which are hereby incorporated by reference herein for all purposes as if fully set forth.

Other useful general references on late transition metal polymerization catalysts and processes are S. D. Ittel, L. K. Johnson and M. Brookhart, Chem.

Rev., 2000, 100, 1169, and G. J. P. Britovsek, et al., Angew. Chem. Int. Ed. , vol. 38, p. 428-447 (1999), which are both hereby included by reference. Be- sides describing the ligands and complexes and how to make them, most of these references also describe the types of olefins that may be polymerized, conditions for activating the transition metal complexes (where needed), use- ful catalyst (s), and other polymerization conditions (e. g. , pressure, tem- perature). These and many other references describe variations on the use of these polymerization catalysts, such as the use of supports, chain transfer agents, mixed (two or more) catalysts, process types (for example gas phase, liquid slurry, etc. ). The conditions described in these documents for carrying out the polymerizations, particularly polymerizations of ethylene, are also ap- pliable to the first process described herein.

In solution or slurry polymerizations organic liquids are usually used as the slurrying medium or solvent (sometimes collectively referred to herein as the solvent). By a solution polymerization is meant the polymer produced is soluble in the solvent during the polymerization, while by a slurry polymeriza- tion is meant that the produced polymer is (largely) insoluble in the liquid (sol- vent) present. The nature of the polymerization does not necessarily imply the state of the catalyst, though most commonly an insoluble heterogeneous catalyst will be used for a slurry polymerization, and a soluble catalyst will be

used for a solution polymerization. Useful solvents preferably include organic compounds which are liquids under the polymerization process conditions, which are relatively inert to the process ingredients, and do not interfere sub- stantially with the polymerization process. Such useful compounds include hydrocarbons such as toluene, xylene, hexane, isobutane, cyclohexane, pentane and 2,2, 4-trimethylpentane, halocarbons such a trichlorobenzene, and can include mixed solvents which include compounds such as ethyl ace- tate and diethyl ether. Preferred solvents are hydrocarbons, and preferred hydrocarbons are saturated hydrocarbons, that is hydrocarbon compounds which do not contain olefinic, acetylenic or aromatic unsaturation. Such compounds include hexane, isobutan, cyclohexane, pentane, and 2,2, 4- trimethylpentane. For example in some instances incorporation of vinyltrialk- oxysilanes into some ethylene copolymers is improved when saturated hydro- carbons are used as the solvent.

Preferred bidentate ligands are either neutral or monoanionic.

Preferred neutral ligands are a-diimines, such as those described in previously incorporated US5880241, US6103658, W00050470 and W00142257. By an"a-diimine"in a general sense is meant a compound having the structure wherein the free bond to the carbon atoms are any organic grouping (includ- ing an organic grouping which is attached to the carbon atom through a het- eroatom and/or is cyclic in nature involving both such carbon atoms) halogen, or hydrogen, and the free bonds to nitrogen are any organic grouping (includ- ing an organic grouping which is attached to the carbon atom through a het- eroatom). In one particularly preferred form (II) has the formula

wherein: R2 and R5 are each independently hydrocarbyl or substituted hydrocar- byl, provided that the atom in R2 and R5 bound to the imino nitrogen atom has at least two carbon atoms bound to it; and R3 and R4 are each independently hydrogen, hydrocarbyl, a heteroa- tom connected monovalent radical, or substituted hydrocarbyl, or R3 and R4 taken together are a heteroatom connected divalent radical, hydrocarbylene or substituted hydrocarbylene to form a ring.

When a heteroatom is present in one or more of groups R2, R3, R4 or R5, that heteroatom is preferably from Group 14 (other than carbon and espe- cially Si), 15 16 or 17 of the Periodic Chart (IUPAC) and, more preferably, N, O, F, Cl or Br.

In general, specific preferred ligands (V) are those preferred in previ- ously incorporated US5880241, US6103658, W00050470 and W00142257.

Preferably R2 and R5 are o-disubstituted (hetero) aryl groups (that is the positions next to the atom of the (hetero) aryl atom bound to the imino nitrogen atom are both substituted). A preferred type of group for R2 and R 5 is a 2,6- disubstituted phenyl group, with the other positions on the phenyl ring option- ally substituted. Such useful groups include 2, 6-dimethylphenyl, 2,4, 6- trimethylphenyl, 2, 6-dichlorophenyl, 2, 6-diisopropylphenyl, 2,6- dimethoxyphenyl, 2-chloro-6-methoxyphenyl, 2, 6-dibromophenyl, 2-methyl-6- methoxyphenyl, 2-chloro-6-methylphenyl, 2-bromo-6-methylphenyl, and 2,6- diphenylphenyl groups in which with 2-and 6-phenyl groups are optionally substituted. Also useful are heteroatom connected monovalent radicals such a pyrryl or substituted pyrryl groups, especially 2,5-disubstituted pyrryl groups.

A preferred grouping for R3 and R4 being taken together to form a ring is herein abbreviated"An".

A useful neutral ligand is

wherein: G is nitrogen or oxygen; and D is nitrogen or phosphorous; provided that: when D is phosphorous and G is nitrogen: R48 and R49 are each inde- pendently hydrocarbyl or substituted hydrocarbyl having an Es of about-0.90 or less ; R50, R51, R52, R53 and R54 are each independently hydrogen, hydro- carbyl or substituted hydrocarbyl ; and R55 is aryl or substituted aryl, provided that any two of R50 R51 R, R53, R and R vicinal or geminal to one an other together may form a ring; when D is phosphorous and G is oxygen: R43 and R49 are each inde- pendently hydrocarbyl or substituted hydrocarbyl having an Es of about-0. 90 or less ; R50 and R51 are each independently hydrogen, hydrocarbyl or substi- tuted hydrocarbyl ; R52 and R54 taken together form a double bond; R55 is not present; and R53 is-OR56,-NR5'R58, hydrocarbyl or substituted hydrocarbyl, wherein R56 is hydrocarbyl or substituted hydrocarbyl, and R57 and R53 are each independently hydrogen, hydrocarbyl or substituted hydrocarbyl ; when D is nitrogen: R43 is hydrocarbyl or substituted hydrocarbyl hav- ing an Es of about-0.90 or less ; R49 and R50 are each independently hydro- gen, hydrocarbyl or substituted hydrocarbyl, or taken together form a ring or a double bond; R51 is hydroge, hydrocarbyl or substituted hydrocarbyl ; G is oxygen; R53 and R54 taken together form a double bond; R55 is not present; R52 is -OR59, -R60 or -R61R62, wherein R59 and R60 are each independently hydrocarbyl or substituted hydrocarbyl, and R61 and R62 are each hydrogen, hydrocarbyl or substituted hydrocarbyl ; provided that when R49 and R50 taken together form an aromatic ring, R43 and R51 are not present.

Ligands of the formula (XII) can be found in previously incorporated U. S. Provisional Application Serial No. 60/294, 794 (filed May 31,2001), along

with methods of making these ligands and their transition metal complexes and methods for using these complexes in olefin polymerizations. Preferred ligands (XII) herein are the same as those preferred in previously incorporated U. S. Provisional Application Serial No. 60/294, 794 (filed May 31,2001).

Preferably when a neutral bidentate ligand is coordinated to the transi- tion metal atom, and particularly when a single neutral bidentate ligand is co- ordinated to a metal atom having a +2 oxidation state, it is preferred that the transition metal complex has the formula

wherein

is a neutral bidentate ligand, M is a Group 8,9, or 10 transition metal, pref- erably Ni or Pd, especially preferably Ni. A catalyst for this system may be a Lewis acid or a protic acid whose anion is a relatively noncoordinating an- ion. If it is a Lewis acid, the Lewis acid should be a strong enough Lewis acid to abstract a Q or Z anion, and with that abstraction a relatively noncoordi- nating anion is formed. Preferably the molar ratio of the Lewis acid to (XVII) is about 500: 1 to about 1: 1, more preferably about 100: 1 to about 2: 1, while the ratio of protic acid to (XVII) is about 0.2 : 1 to about 10: 1, more preferably about 0.5 : 1 to about 2: 1. Using this combination of transition metal complex and catalyst often results in higher copolymer productivity and/or higher polymer molecular weights. Preferred groups for Q and/or Z are halide (chlo- ride or bromide for example), n-allyl, acetylacetonate, aryl (anion such a phenyl), methyl, trialkylsilyl, and (trialkylsilyl) alkyl, especially preferred are (trimethylsilyl) methyl, and methyl, and (trimethylsilyl) methyl is very preferred.

Useful Lewis acids include tris (pentafluorophenyl) borane, tris [3,5- bis (trifluoromethyl) phenyl] borane, triphenylborane, methyl-bis (butylated hy- droxytoluene) aluminum, and di-i-butyl (pentafluorophenoxy) aluminum. Useful

cationic activators include hydrogen tetrakis [3,5- bis (trifluoromethyl) phenyl] borate, hydrogen tetrakis (pentafluorophenyl) borate, [HNMe2Ph] + [B (C6F5) 4]-, [AlMe2(Et2O)2]+[MeB(C6F5)3]=, and (Ph3C) + {B [ (3, 5- CF3) 2-C6H4] 4} These cationic catalysts are especially useful for activating transition metal complexes which have alkyl groups bound to the transition metal, such as a nickel [II] complex which has two methyl anions bound to the Ni atom. A preferred combination of activators is a Lewis acid, and an alkali metal salt of a noncoordinating anion. This combination often has higher polymer productivity than the Lewis acid alone. For example one could use a combination of the Lewis acid tris (pentafluorophenyl) borane and the salt NaBAF. A typical molar ratio for a polymerization would be Lewis acid: alkali metal salt : transition metal of about 5: 1: 1. It also has the advantage of requir- ing small amounts of Lewis acid, thereby decreasing the chances of prema- ture crosslinking of the polymer product (see below).

Useful monoanionic bidentate ligands are:

wherein: R10 is hydrogen, hydrocarbyl or substituted hydrocarbyl ; R", R12, R13, and R14 are each independently hydrogen, hydrocarbyl, substituted hydrocarbyl, an inert functional group, and provided that any two of these groups vicinal to one another taken together may form a ring; R15 is hydrocarbyl, substituted hydrocarbyl or a heteroatom connected monovalent radical ; R16 and R17 are each independently hydrocarbyl, substituted hydrocar- byl or a functional group; Y is CR25R26, S (T), S (T) 2, P (T) Q, NR36 or NR36NR36 ; X is O, CR 27R28 or NR27 ; A is O, S, Se, N, P or As ; Z is O, S, Se, N, P or As ;

each Q is independently hydrocarbyl or substituted hydrocarbyl ; R'8, R'9, R27 R23 R25and R26are each independently hydrogen, hy- drocarbyl, substituted hydrocarbyl or a functional group; R20 is hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group, provided that when Z is O, S or Se, R20 is not present; R21 and R23 are each independently hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group; R24 is hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group; each T is independently =O or =NR30 ; R30 is hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group; R31 and R32 are each independently hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group; R33 and R34 are each independently hydrocarbyl or substituted hydro- carbyl, provided that each is independently an aryl substituted in at least one position vicinal to the free bond of the aryl group, or each independently has an Es of-1.0 or less ; R35 is hydrogen, hydrocarbyl, substituted hydrocarbyl or a functional group, provided that when A is O, S or Se, R35 is not present; each R36 is independently hydrogen, hydrocarbyl, substituted hydro- carbyl or a functional group; m is 0 or 1 ; s is 0 or 1 ; n is 0 or 1 ; and q is 0 or 1 ; and provided that: any two of R18, R19, R27, R28, R21, R23, R25 and R26 bonded to the same carbon atom taken together may form a functional group; any two of R16, R17, R18, R19, R27, R28, R20, R21, R23, R25, R26, R31, R32, R33, R34, R35 and R36 bonded to the same atom or vicinal to one another taken together may form a ring; and when said ligand is (Vlll), Y is C (O), E is O, and R16 and R17 are each independently hydrocarbyl, then R16 and R17 are each independently an aryl

substituted in one position vicinal to the free bond of the aryl group, or R16 and R17 each independently have an Es of-1.0 or less ; Q is oxo, NR41 or PR41 ZisO, NR SorPR each of R37, R38 and R39 is independently hydrogen, hydrocarbyl, sub- stituted hydrocarbyl or a functional group ; r is 0 or 1 ; each R41 is independently hydrogen, hydrocarbyl, substituted hydro- carbyl or a functional group; each R42 is independently hydrogen, hydrocarbyl, substituted hydro- carbyl or a functional group; and provided that any two of R37, R38 and R39 geminal or vicinal to one another taken together may form a ring.

Ligands of the formula (VII) can be found in previously incorporated US6174975, and W00056785, along with methods of making these ligands and their transition metal complexes and methods for using these complexes in olefin polymerizations. Preferred ligands (VII) are those preferred in previ- ously incorporated US6174975Ligands of the formula (Vlil), (IX) and (X) can be found in previously incorporated U. S. Patent Application Serial No.

09/871, 099 (filed May 31,2001), along with methods of making these ligands and their transition metal complexes and methods for using these complexes in olefin polymerizations. Preferred ligands (VIII), (IX) and (X) are those pre- ferred in previously incorporated U. S. Patent Application Serial No.

09/871,099 (filed May 31,2001).

Ligands of the formula (XI) can be found in previously incorporated U. S. Patent Application Serial No. 09/871,100 (filed May 31,2001), along with methods of making these ligands and their transition metal complexes and methods for using these complexes in olefin polymerizations. Preferred lig- ands (XI) are those preferred in previously incorporated U. S. Patent Applica- tions Serial No. 09/871, 100 (filed May 31,2001).

Iron or cobalt complexes, preferably an iron complexes, of a bisimine of a 2, 6-diacylpyridine or a bisimine of a 2, 6-pyridinedicarboxaldehyde, both are neutral tridentate ligands, are also useful as part of the polymerization catalyst system. References describing these catalysts include, for example,

US5955555, W09912981 and W00050470, all of which are hereby incorpo- rated by reference herein for all purposes as if fully set forth. Other types of useful tridentate ligands are found in US6281303, US6294495, US 6313243, US6339161, US6365690, US6369177, W00158874, W00158966, W00168726, W00174830 and W00177186, all of which are hereby included by reference. In addition these and numerous other references describe the synthesis of the ligands and their transition metal complexes as well as the use of the complexes in various polymerization processes. The polymeriza- tions with these complexes may be run similar to the conditions described in these references, using the same types of process conditions (temperature, pressure, etc. ), methods of activating the transition metal complex (if neces- sary), type of process (gas, slurry or solution), etc.

Preferred bisimines of 2, 6-diacylpyridines or 2, 6-pyridinedicarboxaldehydes are the same as those preferred compound as described in previously incorporated US5955555, W09912981 and W00050470. Other preferred bisimines of diacylpyridines are 2, 6- (bis-1- (N- (2,4, 6-trimethylphenyl) imino) ethyl) pyridine and 2, 6- (bis-1- (N- (2, 6-dimethyl-4-t- butylphenyl) imino) ethyl) pyridine. It is preferred that a bidentate ligand, par- ticularly a neutral bidentate ligand, have bonded to it an olefinic group, such as an allyl group.

Polymerizations may be carried out for catalysts based on these lig- ands in the manner and under the conditions generally set out in the afore- mentioned incorporated references. It is, however, particularly noteworthy that it is often preferred to carry out the first process at temperatures some- what higher than are used for many of the ethylene homopolymerizations de- scribed in these references. This often results in higher incorporations of the allyl-or vinylsilane into the copolymers. Typically these"higher"temperature range from about 50°C to about 250°C, preferably about 50°C to about 180°C, more preferably about 60° to about 140°C.

Particularly depending upon the catalyst and type of polymerization process used, and the product desired (for example, level of branching, allyl- or vinylsilane incorporation, and polymer molecular weight) optimum condi- tions for any particular polymerization may vary. The examples described herein, together with information in available references, allow one to optimize

the first process with relatively little experimentation. Generally speaking the higher the relative concentration of allyl-or vinylsilane present in the first pro- cess, the higher the amount of allyl-or vinylsilane which will be incorporated into the final polymer product.

Although the polymerization may be run in gas phase, solution or liquid slurry, it is often preferred to run it in solution or liquid slurry because of the relatively low volatility of the allyl-and vinylsilanes.

In the polymerization process in general, one or more other (than allyl or vinyl) alkenylsilanes may be present in place of or in addition to the vinyls- lane (s). By an"alkenylsilane"herein is meant a silicon compound having the (partial) formula H2C=CHRSi, wherein R72 is alkylen containing two or more carbon atoms. In a preferred compound, R72 is-(CH2) f-wherein f is an integer of 2 to 20. The preferred groups (other than the alkenyl group or allyl group or vinyl group) are the same as listed below for the vinylsilanes.

In the polymerization process in general, but in particular when a bidentate ligand is present as part of the transition metal complex other co- polymerizable monomers may also be present. These include a-olefins, pref- erably of the formula H2C=CHR7°, wherein R70 is n-alkyl containing 1 to 19 carbon atoms and it is more preferred that R70 is methyl, n-butyl or n-hexyl ; a norbornene; a compound of the formula H2C=CH (CH2) dC (O) R71 or H2C=CH (CH2) dR73 wherein d is 0 or an integer of 1 to 20, preferably 0, and R71 is hydrocarbyloxy, preferably alkoxy, substituted hydrocarbyloxy, siloxy, hydroxyl, and R73 is hydrogen or-C (o) R74 wherein R74 is hydrocarbyl or sub- stituted hydrocarbyl ;; and cyclic olefins such as cyclopentene and substituted cyclopentenes. The structures of all these polymers with respect to the ethyl- ene and allyl-or vinylsilane units present are similar to those for polymers containing repeat units derived from only ethylene and one or more allyl-or vinylsilanes.

In the present polymerization process, allyl-or vinylsilanes are particu- larly useful in the polymerization, because they yield benefits other than merely copolymerizing the silane into the resulting polyolefin. It has been found that allyl-or vinylsilanes, particularly allyl-or vinylsilanes in which at least one alkoxy group is bound to the silicon atom, often give higher yields of

ethylene copolymers than when no such allyi-or vinylsilanes are present, or when other alkenylsilanes are present. Also the incorporation of the allyl-or vinylsilane, especially the vinylsilane, into the copolymer, is higher than other similar alkenylsilanes. See Tables 33 and 34 for some of these effects.

Another unusual aspect of the copolymerization of vinylsilanes is that one would expect (without so-called chain walking) that the repeat unit de- rived from the vinylsilane would be (I). From an allylsilane one would expect a similar repeat unit, (XIX). However chain walking usually takes place in the process when a neutral or monoanionic bidentate ligand is present as part of the transition metal complex, resulting in the vinylsilanes being present in branches of the formula- (CH2) eSi= wherein e is an integer of 1 or more.

Analogous structures are formed from allylsilanes, where without chain walk- ing e would be 1, but structures in which e is 0 or 2 or more are found. This is indicative of chain walking of the active metal center away from the silicon atom, and it happens to an unusually high degree compared to other func- tional (or polar) olefins that are copolymerized by these catalysts. It is be- lieved that the longer the branches on a polyethylene or other polyolefin, the more effective the branches are in depressing the melting point of the polymer and/or improving the polymer rheology for certain uses. It may also help the polymer crosslink by faster hydrolysis (see below).

In the above-mentioned polymerization processes, the transition metal complexes may in and of themselves be active catalysts, or may be"acti- vated"by contact with a cocatalyst/activator. More than one such catalyst may be used in combination.

The catalysts herein may be"heterogenized"by coating or otherwise attaching them to solid inorganic or organic supports, such as silica, alumina, polyethylene, or polystyrene. Where an active catalyst species is formed by reaction with a compound such as an alkylaluminum compound or Lewis acid, a support on which the alkylaluminum compound or Lewis acid may be first coated or otherwise attached is contacted with the transition metal compound precursor to form a catalyst system in which the active transition metal cata- lyst is"attached"to the solid support. These supported catalysts may be used in polymerizations in organic liquids. They may also be used in so-called gas

phase polymerizations in which the ethylene and any comonomers being po- lymerized are added to the polymerization as a gas and no liquid supporting phase is present. For materials for and methods of making heterogeneous catalysts see G. G. Hlatky, Chem. Rev., vol. 100, p. 1347-1376 (2000).

The polymerization processes described herein may be run in any manner common for coordination olefin polymerization processes, such as batch, semi-batch, and continuous. The processes may be run in solution, slurry or gas phases. Typically a gas phase polymerization process is run as a fluidized bed process in which polymer particles are fluidized by ethylene (or other gaseous monomer) and optionally an inert gas.

Hydrogen or other chain transfer agents such as silanes (for example trimethylsilane or triethylsilane) may be used to lower the molecular weight of polyolefin produced in the polymerization process herein. It is preferred that the amount of hydrogen present be about 0.01 to about 50 mole percent of the olefin present, preferably about 1 to about 20 mole percent. The relative concentrations of a gaseous olefin such as ethylene and hydrogen may be regulated by varying their partial pressures.

Further details on cocatalysts and the use thereof, as well as various other catalyst and polymerization process details, can be found in the previ- ously incorporated references.

A preferred vinylsilane for use in the present invention has the formula H2C=CHSiRRR (XX) wherein R is a hydrolyzable group, and R64 and R65 are each independently a hydrolyzable group, siloxy, hydrocarbyl or sub- stituted hydrocarbyl, provided that any two of R63, R64 and R65 together may form a ring, or all of R63, R14 and R65 together may form a ring structure (see Example 135 below for instance). By a hydrolyzable group in this context is meant a group bound to silicon which is hydrolyzed when exposed to liquid water or water vapor at 25°C. Useful hydrolyzable groups include hydrocar- byloxy, dialkylketoximino, acyloxy, amino, and N-amido, and hydrocarbyloxy, especially alkoxy or aryloxy, is a preferred hydrolyzable group. Preferably in any vinylsilane there is no halogen bound directly to a silicon atom. In an- other preferred vinylsilane, only one vinyl group is present in the compound.

In another type of preferred vinylsilane, R63 is a hydrolyzable group, and R64 and R65 are each independently hydrocarbyl, especially alkyl, or a hydrolyz-

able group. In a more preferred vinylsilane R63 is alkoxy, and R64 and R65 are each independently alkyl or alkoxy. In another type of preferred vinylsilane R64 and/or R65 are fluorinated alkyl. Preferred alkoxy groups for the vinyls- lane are methoxy, ethoxy, t-butoxy and i-propoxy, and methoxy and ethoxy are especially preferred, and a preferred alkyl group is methyl. A preferred aryloxy group is phenoxy. In (XX) any combination of these preferred struc- tural features may be present. Specific preferred vinylsilanes include vinyltri- methoxysilane, vinyltriethoxysilane, vinyltri-i-propoxysilane, vinyltri-t- butoxysilane, vinyltriphenoxysilane, vinylmethyldimethoxysilane, vinylemthyl- diethoxysilane, vinyldimethylmethoxysilane, vinyidimethylethoxysilane, vinyl- phenyldimethoxysilane, vinylphenyldiethoxysilane, vinyldiphenylmethoxysi- lane, vinyidiphenylethoxysilane, and vinyltris (2-methoxyethoxy) silane. An- other type of preferred vinylsilane is a siloxane having at least one (preferably one or two, more preferably one) vinyl group. Preferred polymerization proc- esses and copolymers herein also contain any of the above preferred vinyls- lanes, when vinylsilanes are used to make the copolymers.

A preferred allylsilane for use in the present invention has the formula H2C=CHCH2SiR63R64R65 (XV), wherein R63, R64 and R65 are as defined above.

Preferred (and nonpreferred) groups for R63, R64 and R65 are the same as in (XX). A particularly preferred hydrolyzable group for (XV) is methoxy. Spe- cific preferred allylsilanes are analogous to the specific preferred vinylsilanes.

Preferred polymerization processes and copolymers herein also contain any of the above preferred allylsilanes, when allylsilanes are used to make the co- polymers.

It has also been found that certain allyl-and vinylsilane monomers bearing fluorinated groups, especially fluorinated alkyl groups, may be co- polymerized with olefinic comonomers. Note that these fluorinated substitu- ents are included within the definition of substituted hydrocarbyl, the substitu- tion being fluorine and possibly other substituents are also present. Silanes which may be copolymerized include [R43 (CH2) m] xR44ySi (OR) z [(CH2)kCH=CH2] wherein each R43 is independently perfluoroalkyl optionally containing one or more ether groups; R44 =is substituted hydrocarbyl or hydrocarbyl, m is an in- teger of 2 to 6, k is 0 or 1 (vinyl or allyl) x is 1, 2 or 3, y is 0, 1 or 2, and z is 0, 1 or 2, provided that x+y+z=3. Suitable functional groups for R43 include

ether, chlorine, bromine or iodine, ester, sulfonic acid (-S03H), and sulfonyl halide. The perfluoroalkyl group may also be substituted with hydrogen. A sulfonic acid group containing monomer does not have to be polymerized di- rectly. It is preferably made by hydrolysis of a sulfonyl halide group already present in an already made polymer. It is preferred that the perfluoroalkyl group contain 2 to 20 carbon atoms and preferred perfluoroalkyl groups are- F (CF2) b- wherein b is 2 to 20, and F (CF2) dOCF2CF2- wherein d is 2 to 20. A preferred olefinic comonomer is ethylene or a linear a-olefin, and ethylene is especially preferred. Polymerizations may be carried out with many of the catalysts described herein.

The resulting fluorine containing polymers may be useful for compatibi- lizing fluorinated and nonfluorinated polymers, for changing the surface char- acteristics of urinated or nonfluorinated polymers (by being mixed with them), as molding resins, etc. Those polymers containing functional groups may be useful where those functional groups may react or be catalysts. For instance, if a polymer is made with a sulfonyl fluoride group that group may be hydrolyzed to a sulfonic acid, which being highly fluorinated is well known to be a very strong acid. Thus the polymer may be used as an acid catalyst, for example for the polymerization of cyclic ethers such as tetrahydrofuran.

The hydrolytic reactivity of allyl-and vinylsilane copolymers which contain hydrolyzable groups is useful in a number of applications. Hydrolysis may lead to the formation of a reactive intermediate silanol group. This Si-O- H functionality can then undergo self-condensation, evolving water to form stable Si-O-Si bonds to crosslink the polymer. Alternatively, the Si-O-H func- tionality can react with inorganic, hydroxyl-containing surfaces such as glass, ceramics, or surface-oxidized metals forming adherent bonds to those sur- faces. Surface-oxidized metal surfaces would include the Al-O-H and Al-O functionality of exposed aluminum, the Fe-O-H and Fe-O functionality of ex- posed steel, and many other similar species.

In many polymer applications it is desirable to have staged curing or adhesion. Thus, it is sometimes desirable to incorporate two or more different allyl-or vinylsilanes monomers into the polymerization. Terpolymerization of ethylene or other olefin with vinyltrimethoxysilane and vinylmethyldimeth-

oxysilane would provide two cure sites with differing reactivity, such that initial faster reaction would occur at the trimethoxysilyl group and a slower final curing reaction would occur at the methyldimethoxysilyl group. In adhesive applications, this differential curing could aid fabrication by providing quick ini- tial tack followed by longer-term formation of a stronger adhesive bond.

The low-temperature crosslinking reaction provided by the siloxane functionality is of use in wire and cable applications. In addition, siloxane crosslinking provides increased melt-strength required for the foaming of polyolefins.

The rates of hydrolysis and condensation of alkoxysilane functionalities on a polymeric backbone are usually dependent upon their concentration, the pH of the siloxane microenvironment, the presence of solvents or plasticizers, the molecular weight of the polymer, the degree of crystallinity of the polymer, the presence of catalysts, the nature of the organic groups on the silicon atom and the permeability of water in the polymer. For instance, the rate of hy- drolysis of a trialkoxysilyl group usually decreases with increasing length of the alkyl chain of the alkoxy substituent or the presence of branching in the alkyl chain near the oxygen atom. The rate of hydrolysis usually decreases in the order Si (OR) 3 > Si (OR) 2R'> Si (OR) R'2, wherein R and R'are hydrocarbyl or substituted hydrocarbyl groups.

The presence of phenyl as R'usually decreases the rate of hydrolysis more than, for example, methyl. The presence of additional polar functionality in R usually increases the rate of hydrolysis in that methoxyethyl hydrolyzes faster than n-butyl though they have the same number of atoms in the chain and both acetoxy and methylethylketoxinimo hydrolyze faster still. Incorpora- tion of two or more of the alkoxy groups on the silane in ring structures can slow or speed the hydrolytic reactions depending upon the ring size. In al- kylalkoxysilanes, it is also possible to incorporate both the alkyl and alkoxy groups in a ring structure. it is also likely that the rates of hydrolysis and condensation of alk- oxysilane functionalities in a polymer matrix are also dependent upon the na- ture of the polymer backbone and the location of the alkoxysilane with regard to the polymer backbone. Alkoxysilane groups tied directly to the main chain

of a polymer molecule are usually less mobile than alkoxysilane groups teth- ered at the end of a short chain. A crosslinking process requires that a mini- mum of two silanol groups react to form a Si-O-Si linkage, but often, these condensations result in the formation of Si-O clusters. The often higher func- tional group mobility afforded by being tethered to a branch rather than a main backbone may afford a higher degree of clustering. Also, a higher amorphous content in the polymer or exclusion of the siloxane functionality from crystal- line regions of the polymer would increase clustering.

In a variety of adhesion and other applications, it may be advantageous to incorporate one or more other functional groups in addition to those af- forded by alkoxyvinylsilane monomers. Thus terpolymerization of alkoxyvinyl- silanes and acrylic with ethylene or alpha-olefins may be advantageous. For example, a polymer resulting from ethylene polymerization with vinyltrimeth- oxysilane and methyl acrylate often would be useful for adhesion between glass and acrylic polymers.

While it is often of benefit to have at least one alkoxy group on silicon in addition to the allyl or vinyl group, the alkoxysilane functionality may also be pendant in the monomer. Thus a molecule such as would provide two different types of alkoxysilane groups with differing reactiv- ity all in a single monomer.

The allyl-or vinylsilane may be introduced into the polymerization pro- cess in much the same way as any other olefin is introduced. If it is a gas phase polymerization the allyl-or vinylsilane may be volatilized and then in- troduced as a separate stream, or mixed with ethylene before introduction into the reactor. Alternatively, one may use the"condensing phase"mode of op- erating a gas phase polymerization and introduce the allyl-or vinylsilane monomer in the condensing phase. If there is a liquid phase present (slurry or solution for example) in the polymerization it may be introduced as a liquid, for instance in solution in the liquid phase or as a separate stream. If the polym- erization is a batch or semibatch process it may be present before the polym- erization is started or added at or close to the beginning of the polymerization

reaction. The allyl-or vinylsilane itself may be the liquid phase, or it may be present as a component of the liquid phase. Concentrations of the allyl-or vinylsilane in the liquid phase may be from about 0. 1 % by volume to about 40% by volume, more preferably about 0. 1% to about 10% by volume.

Isolation of the polyolefin product may be by any means normally used to isolate polymers from such polymerization processes, although most of the time one would not want to"prematurely"crosslink the polyolefin if the allyl-or vinylsilane had hydrolyzable groups present. Care should therefore be taken not expose the polyolefin to conditions that would cause premature crosslink- ing, for example exposure to moisture coupled with addition of catalysts for the crosslinking reaction and/or excessive heating of the polyolefin.

As described above, previous ethylene polymers which contain vinyl- silanes were made by a high pressure polymerization process or were grafted onto a preexisting polymer, usually using a free radically catalyzed process.

These polymers have certain structural characteristics, and the table below shows the percentage of various structures containing silanes in each poly- mer, as measured by 13C NMR spectroscopy. The percentage given are the percent of the total amount of silane present in the polymer. In Table A, G is a graft polymer, and HP is a high pressure copolymer. The"n"in the Table refers to"n"in (XVI).

Table A Polymer Type Si Comonomer Other comonomer % Branching mole % mole % n=0 n=1 n=2 n=3 n=4+ HP VTMoS, 0. 5 methyl acrylate, 7.0 16 0 0 0 84 HP VTMoS, 0.5 butyl acrylate, 4.6 60 0 0 0 60 G VTMoS, 0.28 none 0 0 100 0 0 The n=4+ values for the HP polymers are believed to be chain ends, and/or result from a"back biting"mechanism known for radical-type polymerizations.

When compared with the data of Table B (below), the data in Table A show that the structures of previously known vinylsilane containing polymers are different from the polymers described herein.

Many of the late metal catalysts used herein have the potential to form vinylsilane copolymers with high degrees of branching due to chain-walking.

Even hyperbranched or dendritic type structures are possible. The level of

vinyisilane incorporation can be varied from low to high in these amorphous copolymers and their state can be varied from solids to free-flowing oils de- pendent on the amount and type of branching, the molecular weight, the level of vinylsilane and other comonomer incorporation, etc.. High vinylsilane in- corporation, high levels of branching, the presence of longer branch lengths, and the presence of branches on branches all typically lower the crystallinity of the copolymer, as does the incorporation of alpha olefins such as 1-butene, 1-hexene and 1-octene. The amorphous nature of these vinylsilane copoly- mers is unique as compared to the higher crystallinity of the current commer- cial radical vinylsilane copolymers and grafted vinylsilane polymers.

Numerous novel copolymers incorporating the allyi-or vinylsilanes are described herein. The first copolymer is a copolymer of ethylene and one or both of an allyl-and vinylsilane having a density of 0.920 or more, preferably about 0.930 or more, and especially preferably about 0.940 or more. Previ- ous copolymers of ethylene and vinylsilanes were made by high pressure free radical copolymerization of these monomers, which leads to a low density polyethylene (LDPE) type polymer having some copolymerized vinylsilane.

LDPEs made by high pressure polymerization have a different branching pattern than the polymers described herein, and because the LDPE usually has a substantial number of total branches, it typically has a relatively low density. Some of the polymers made herein have relatively low amounts of branching and so have higher densities. Polymers made using iron or cobalt complexes of tridentate ligands are believed be essentially branchless, except for the"branches"due the silyl groups of the allyl-or vinylsilanes themselves.

Amorphous polymers tend to have relatively low densities.

The second copolymer herein has a branching level of at least about 10 alkyl branches per 1000 methylene groups [after correction (subtraction of) for end of chain methyl groups, and excluding lower alkyl groups bound di- rectly to silicon]. Such branching levels are measured by NMR and these methods are described in the section on NMR analysis. Preferably these polymers have at least about 20 branches per 1000 methylene groups, and more preferably have at least about 40 branches per 1000 methylene groups.

Also preferably at least about 20 mole percent of these branches in the poly- mer are methyl branches.

A third polymer has at least 2 methyl branches per 1000 methylene groups, more preferably at least about 5 methyl branches per 1000 methylene groups in the copolymer. This too is measured by NMR, and the same"cor- rections"and"exclusions"apply to this third polymer as the second polymer.

A fourth copolymer has a melting point of at least about 115°C, more preferably at least about 120°C when measured by Differential Scanning Ca- lorimetry according to ASTM D3417, at a heating rate of 10°C/min, and the melting point is taken as the peak of the melting endotherm.

As shown in the 13C NMR spectrum for the polymer produced in Exam- ple 34 (see Figure 2 and lis, ting after Table 15) at least some of the vinylsilane copolymers, fifth copolymers, contain the group wherein represents the rest of the polymer (chain), and the three free bonds to silicon represent the other groups bound to the silicon, for ex- ample three alkoxy groups. The structure does not imply whether the olefinic bond is cis or trans. It is theorized that these groups may be end groups for the polymer chains, which would be advantageous from the point of view of the physical properties of the ensuing crosslinked polymer. (XIII) may (theo- retically) arise by a p-hydride elimination chain transfer mechanism when the vinyl silane is attached to the growing polymer molecule. In some polymers, a structure such as (XIII) may represent about 0.5 to about 50 mole percent of the vinylsilane (based on the total amount of vinylsilane) incorporated into the copolymer, preferably about 1 to about 30 mole percent, and especially pref- erably about 3 to about 20 mole percent. All of these minimum and maximum limitations may be mixed with each other. Preferably the end groups (XIII) are at least 0.001 mole percent, more preferably at least 0.01 mole percent, and especially preferably at least about 0.1 mole percent of the total repeat units (ethylene, silane and any other comonomers) in the copolymer. For example in the polymer of Example 34, the 13C NMR (see Figure 2) indicates that about 16 mole percent of the vinylsilane incorporated is present as (XIII).

A sixth copolymer of ethylene, one or both of an allyl-and a vinylsilane, and optionally other copolymerizable monomers, contains at least 1.0 or more mole percent (total) of incorporated allyl-or vinylsilane, more preferably at

least about 2.0 mole percent, and especially preferably at least about 3.0 mole percent, very preferably at least about 5.0 mole percent. Mole percent- ages are based on the total amount of all repeat units in the copolymer.

As shown in the 13C NMR spectrum for the polymer produced in Exam- ple 360 and 361, at least some of the vinylsilane copolymers, seventh co- polymers, contain the group wherein represents the rest of the polymer (chain), and the three free bonds to silicon represent the other groups bound to the silicon, for ex- ample three alkoxy groups. It is theorized that these groups may be end groups for the polymer chains, which would be advantageous from the point of view of the physical properties of the ensuing crosslinked polymer. In some polymers, a structure such as (XXI) may represent about 0.5 to about 80 mole percent of the total end groups which contain silicon atoms. Preferably the end groups (XXI) are at least 0.001 mole percent, more preferably at least 0.01 mole percent, and especially preferably at least about 0.1 mole percent of the total repeat units (ethylene, silane and any other comonomers) in the copolymer. In such seventh copolymers it is preferred that at least some of incorporated silicon containing groups are of the formula (xi), and in such groups (XVI) in at least about 10 mole percent or more n is 4 or more, and/or in at least about 5 mole percent or more of (XVI) n is 0.

Aside from the alkyl branching described above, which is believed due to a phenomenon called"chain walking" (see World Patent Application 96/23010), in many of the allyl-or vinylsilane containing copolymers herein the silicon containing monomer is incorporated into the polymer in unusual ways (also believed due to chain walking). In a"normal"olefin coordination polymerization (if it could be achieved with these olefinic silanes) it would be expected that the repeat unit derived from a vinylsilane would be

wherein n is 0, while in a repeat unit from an allylsilane n would be 1. While these results are sometimes obtained, very often n is not the"expected"num- ber shown above. This is illustrated in Table B below, where the branching analyses on the incorporated olefinic silane monomers (as a percent of total incorporated silane monomer, less any silane monomer incorporated as un- saturated end groups) in copolymerization with ethylene are given for selected Examples from this application.

Table B Ex. Monomer Type n=0, % n=1, % n=2, % n=3, % n=4+, % 103 vinyl 25.6 20.0 21. 0 7. 8 25. 6 104 vinyl 29.6 26.2 17.9 9.6 16.7 106 allyl 16.1 41.4 16.3 12.5 13.7 107 allyl 5.9 43.4 26.3 9.1 15.3 108 vinyl 43.3 31.3 16.0 3.4 6.0 109 vinyl 28.9 22.7 19.8 7.5 21. 2 111 allyl 6.4 45. 8 25.8 8.0 14.0 116 vinyl 36.7 16.5 8.8 11.5 26. 5 120 vinyl 31.9 20.7 31.5 5.9 10. 0 123 vinyl 100. 0 124 vinyl 100.0 125 vinyl 28.1 29.6 19.9 7.4 15.1 126 vinyl 34.9 14.8 25.3 7.6 17.4 129 vinyl 40.4 21. 3 19. 2 1. 4 17. 6 These results show that in many instances the"expected"repeat unit from the allyl-or vinylsilane is often a minority of the total incorporated units.

Indeed a wide range of n values is obtained (the NMR method used can't dis- tinguish between different n's having a value of 4 or more). For example such vinylsilane copolymers often have at least about 5 mole %, more preferably at least about 10 mole % of incorporated silane monomer wherein n is 0,1, 2,3 and 4+, or any combination of such n's or single n which are (is) about 5 mole percent or more, or about 10 mole percent or more. In some vinylsilane co- polymers n=1 is about 15 mole percent or more, preferably about 20 mole percent or more of the total vinylsilane monomer incorporated and/or n=3 is about 4 mole percent or more, preferably about 10 mole percent or more of the total silicon monomer incorporated. It should be emphasized that any combination of preferred amount of"n"in silane containing branches de- scribed in this paragraph may be combined with any other preferred amount

(not just values of"n", but also alkyl branching, polymer density, polymer melting points, etc. ) and that these molar percentages do not include olefinic silanes that are incorporated as olefinic end groups such as (XIII) and (XXI).

Allylsilane copolymers often have at least about 5 mole %, more pref- erably at least about 10 mole % of incorporated silane monomer wherein n is 0,1, 2,3 and 4+, or any combination of such n's or single n which are (is) about 5 mole percent or more, or about 10 mole percent or more. In some al- lylsilane copolymers n=0 is about 4 mole percent or more of the total allylsi- lane monomer incorporated, and/or n=2 is about 5 mole percent or more, more preferably about 10 mole percent of more of the total allylsilane incorpo- rated, and/or n=3 is about 5 mole percent or more of the total silicon monomer incorporated. It should be emphasized that any combination of preferred amount of"n"in silane containing branches described in this paragraph may be combined with any other preferred amount (not just values of"n", but also alkyl branching, polymer density, polymer melting points, etc. ) and that these molar percentages do not include allylsilanes which are incorporated as ole- finic end groups such as (XIII).

The"n value"of branches formed by incorporation of the olefinic si- lanes will vary to some extent with the olefinic silane chosen. For example when the other three groups on silicon are alkyl, n tends to be the value from a"normal"polymerization, for example 0 when a vinylsilane is used. When there are three alkoxy groups bound to the silicon of an allyl-or vinylsilane, the value of n tends to range broadly. When relatively low temperatures and/or particularly high ethylene pressures are used (particularly in combina- tion) n tends to be more like that from a"normal"polymerization, that is n tends to be 0 when a vinylsilane is used, and 1 when an allylsilane is used, although a range of"n"values is still often obtained (by tending to be a more "normal"polymerization may mean that a larger percentage of n is 0 or 1).

In another preferred vinylsilane copolymer, in at least about 70 mole percent, more preferably at least about 80 mole percent and very preferably at least about 90 mole percent of the repeat units n is 0. Preferably the olefinic silane was a vinylsilane, and/or a comonomer is ethylene and/or one or more a-olefins of the formula H2C=CH (CH2) tCH3 wherein t is 0 or an integer of 1 to

20 and/or carbon monoxide, and more preferably the comonomer is ethylene.

Other comonomers, such as acrylate esters, vinyl ketones, acrylic acid, epoxy group containing acrylate esters, selected olefins containing epoxy, ester, keto, orthoester, silyl, sulfone, and fluorine, which are known in the art to be copolymerized by some of the polymerization catalysts described herein, may also be present (and copolymerized). Most preferably this copolymer is a co- polymer of a vinylsilane and ethylene.

When Pd catalysts (as opposed for example to Ni catalysts) are used to form the vinyl-or allylsilane copolymer other branching patterns may result, see in particular Tables 65, 66,68 and 69 below. Herein the values of"n"in (XVI) in the polymerization of vinylsilanes may be: n=0 less than 10 mole per- cent (of the total Si groups present, not including unsaturated end groups); n=1 less than 10 mole percent; n=3 at least 10 mole percent; and n=4+ at least about 40 mole percent. In ethylene copolymers of the vinylsilanes made with Pd catalysts, typically at least 30 alkyl branches per 1000 methylene groups are present in the polymer. Typically there are: at least about 10, more typically at least about 20, methyl branches per 1000 methylene groups; at least about 0.5 but no more than about 5 n-propyl branches per 1000 methylene groups; and no more than about 25 n-butyl branches per 1000 methylene groups. Preferably these copolymers contain at least about 1.0 mole percent, more preferably at least about 3 mole percent of copolymerized vinylsilane.

Amorphous copolymers of ethylene and vinyl-or allylsiianes, and op- tionally small amounts (<5 mole percent) of other comonomers, are unique and are amorphous because of the relatively high levels of alkyl group branching present due to the"normal"chain walking that occurs when ethyl- ene is polymerized alone (see WO 96/23010).

In all of the copolymers described herein it is preferred that at least about 0.05 mole percent of the total of all repeat units are derived from an al- lyl-or vinylsilane, more preferably at least about 0.10 mole percent, still more preferably at least about 0.3 mole percent, again still more preferably at least about 0.6 mole percent, and especially at least about 1.0 mole percent.

It will be recognized that any particular copolymer produced by the pro- cesses herein may meet the limitations of any, some or all of the first, second,

third, fourth, and so on, polymers, and so"properties" (limitations) of each of these polymers as described above may be applied to any of the other poly- mers, in any combination. For example a copolymer may have 12 branches per 1000 methylene groups, and/or have 4 branches which are methyl branches, and/or have a density of >0.930, and/or have a melting point of >115°C.

The copolymers made in the polymerization process, for instance as described above, are often novel, and so are their crosslinked counterparts.

The polymers may be crosslinked by hydrolysis of hydrolyzable groups on the silicon, and subsequent condensation of the silanol groups formed. These reactions may be almost simultaneous or they may be sequential.

In general, a condensation catalyst is utilized in conjunction with the siloxane-containing polymers to promote hydrolytic crosslinking andlor adhe- sion. The condensation catalyst is chosen from any compound that will pro- mote the condensation reaction between silanol groups produced by hydroly- sis of the initial hydrolyzable groups so as to cure the polymeric system by the formation of-Si-O-Si-bonds. Examples of suitable catalysts include carboxy- lates of such metals as tin, titanium, bismuth, lead and zirconium. The silanol condensation reaction may be interpolymer to effect crosslinking or may be the reaction of polymeric silanol groups with other silanol or metal-OH groups on inorganic surfaces to effect adhesion.

Examples of suitable tin catalysts include dibutyltin diacetate, dibutyltin dilaurate, tin tripropyl acetate, stannous octoate, stannous oxalate, stannous naphthenate, dibutylbis (2, 4-pentadionate) tin. Specific titanates include tetra butyl titanate, titanium diisopropoxy-bis-ethylacetoacetate, tetraisopropoxyti- tanate and tetrabutoxytitanate. Additionally, amines such as triethylamine, diethylenetriamine, butylamine, octylamine, dibutylamine, monoethanolamine, diethanolamine, triethanolamine, diethylenetriamine, triethylenetetramine, cy- clohexylamine, benzylamine, diethylaminopropylamine, xylylenediamine, tri- ethylenediamine, guanidine, diphenylguanidine and morpholine can be used as catalysts.

Preferred condensation catalysts are selected from the above de- scribed tin carboxylates, titanium carboxylates or mixtures thereof. It has also been found that addition of a minor amount of an organic amine, such as

lauryl amine at about 0.1 to about 2 parts by weight for each 100 parts by weight of the polymer is useful when employing the tin compounds since it acts as a stabilizer. Very preferred catalysts are tin (IV) carboxylates since these have been observed to provide the polymers most stable to storage prior to crosslinking or adhesion.

The silane containing copolymers described herein are useful in many applications. In general, the ability of the silane groups to hydrolyze and self condense (for example to crosslink the copolymer) and/or to bond to other substrates is the basis for many of these uses. As mentioned above, these copolymers can be made with a wide range of silane content, molecular weight, and crystallinity. In the list of uses below, uncrosslinked polymer properties that are believed to be preferred for the use listed are given by the following abbreviations : HMW, high molecular weight ; LMW, low molecular weight, including oligomers ; HS, high silane content, above about 1.0 mole percent of the polymer repeat units; LS, low silane content, below about 0.5 mole percent of the polymer repeat units; HC, highly crystalline, for instance for a polyethylene approaching or at the crystallinity of a typical high density polyethylene ; LC, low crystallinity, having a total heat of fusion above 30°C of less than 5 J/g. When more than one of these preferred properties are listed for a particular use, one, some or all of them may be present in any combina- tion.

Wire coating, insulation, or jacketing for electrical wires. HMW House siding HMW . Pipes, especially hydraulic pipes. HMW, HC Foams, for example for use in sporting goods, toys, packaging, and medical uses. HS, HMW Components for automotive coatings and other types of coat- ings (paints). LC, HS Safety glass interlayer. HS, LC (preferably very transparent) . Seismic bearings. HS, LC Packaging film for various items such as food, and medical equipment.

Polymer modifier/polymer additives/polymeric tougheners, for example as additives to multi-component thermoplastic elasto- mers.

Gaskets (e. g., form-in-place gaskets) for gas-tight applications since the permeability of the cured compositions is close to that of the unmodified polymer. LMW, HS w Elastomeric seals for insulating glass structures and formulation of sealants for construction and vibration damping applications (e. g. , in automobiles, appliances, disc drives, and audio speak- ers). LC Sheets materials, for example pond liners. HMW Fibers.

Rotomolding (powder), for example for making fuel tanks chemical tanks, and underground storage tanks. HMW, LS Medical instruments and apparatus.

Films and tapes. HMW Parts for radiant heating systems. HC, HMW . Adhesives (component). HS, LMW Release film.

Stain resistant nonwoven fabric (from fibers).

. Films, sheets and other forms for acoustic damping.

Cladding for glass bottles, steel and other wire (aside from electrical wire) and rods such as reinforcing rods. HMW Packaging materials, for example in the form of sheets, foams and films HMW . Heat shrinkage tape. HMW, HC Cable (such as telephone cable, optical fiber cable, and coaxial cable) jacketing. HMW 'Sheets for coating/laminating onto other substrates such as metal or other resins, such as coating for house siding. HMW Caulks LMW, HS Dispersants, for example for pigments, inks and metal oxide nanoparticles.

Modifier for inorganic polymer.

Waxes, for example ski waxes. LMW In some of these applications, it is contemplated that the formulated moisture sensitive copolymers will be packaged in hermetically-sealed con- tainers such as a cartridge or flexible tube. Such containers can be stored for extended periods and, when needed, the formulations contained therein can be dispensed (extruded) using a caulking gun, or the like.

To avoid premature crosslinking, it may be desirable to add a stabilizer (towards crosslinking) to the allyl-or vinylsilane copolymers. Such stabi- lizer (s) may be added during the polymerization, isolation, and/or storage of the stages of the process for making the polymer, and the stabilizer (s) chosen for any or all these stages may be the same or different. A useful stabilizer may be a Lewis base, such as an amine, ester, alkoxysilane not containing a vinyl or allyl group, etc. During the copolymerization stage itself, even the presence of a Lewis base termonomer, such as an acrylate ester, can act as a stabilizer (e. g., Example 59). For some illustrations of the use of such stabi- lizers in the processes herein, see Examples 59-75 where Et3N sometimes (EtO) 3Si-i-Bu or (EtO) 4Si were added during the isolation procedure. See also Example 61 vs. 98 in Table 30, and Examples 99 vs. 100 in Table 31, where the addition of ethyl acetate and (MeO) 3Si (i-Bu), respectively, during the co- polymerization stage resulted in polymers with measurable melt indices vs.

"no flow"for polymer produced in the absence of these Lewis bases. As may be expected from the fact that Lewis bases stabilize these polymers against "premature"crosslinking, maintaining the levels of any Lewis acids present during the polymerization stage as low as possible (commensurate with ob- taining the desired polymer product) is also believed to help prevent prema- ture crosslinking. included in this invention are copolymers of vinylsilanes and allylsi- lanes based upon nonhydrolyzable groups, including vinyl-or allyltrialkylsi- lanes and vinyl or allylsiloxanes. Incorporation of these comonomers is useful in modifying a number of copolymer properties, including crystallinity and surface properties, for instance hydrophilicity and/or lipophilicity. Potential general uses of non-hydrolyzable, low-crystallinity silane copolymers include

viscosity modifiers, dendrimers, oils, greases, waxes, lubricants, and disper- sants. In particular, siloxane-derived copolymers are potentially useful as pressure-sensitive adhesives. Copolymers derived from vinyl-and allyltrial- kylsilanes are useful for modifying copolymer crystallinity. Copolymers de- rived from vinylsilanes and allylsilanes based upon fluorinated nonhydrolyz- able alkyl or siloxy groups are particularly useful for modifying surface proper- ties.

EXAMPLES Abbreviations The following abbreviations are used in the Examples: AHf-heat of fusion 1 B1-percentage of total methyl branches occurring in sec-butyl branches 1 B2-percentage of total ethyl branches occurring in sec-butyl needed branches acac-acetylacetonate or 2,4-pentanedionato Am-amyl <BR> <BR> <BR> <BR> ATEoS-allyltriethoxysilane<BR> <BR> <BR> <BR> <BR> ATMoS-allyltrimethoxysilane BAF-tetrakis [3, 5-bis (trifluoromethyl) phenyl] borate BArF-tetrakis (pentafluorophenyl) borate BHT-butylated hydroxytoluene Bu-butyl EB-end-of-branch, refers to the functional group of a polar olefin, e. g., the ester group of an acrylate or the Si (OR) 3 group of an allyl-or vinylsilane, being located at the end of a branch of the polymer E-10-U-ethyl 10-undecenoate EG-end group, refers to the functional group of a polar olefin, e. g. , the ester group of an acrylate or the Si (OR) 3 group of an allyl-or vinylsilane, being located in an unsaturated end group of the polymer EGPEA-ethylene glycol phenylether acrylate eoc-end-of-chain Et-ethyl

GPC-gel permeation chromatography hex-hexyl IC-in chain (bound directly to the main polymer chain) MA-methyl acrylate MAO-methylaluminoxane Me-methyl MI or M. I.-melt index, usually at a load of 2.14 kg MMAO-methylaluminoxane containing a minority of isobutyl groups in place of methyl groups (IP refers to a grade available from Akzo-Nobel, Inc.) Mn-number average molecular weight Mp-peak molecular weight m. melting point Mw-weight average molecular weight NF-no flow PD or PDI-polydispersity, Mw/Mn pk-peak Ph-phenyl PMAO-IP-polymethylalumoxane in toluene, 13 wt % Al, from Akzo- Nobel Chemicals Pr-propyl RI-refractive index RT-room temperature SMAO-A grade of MAO treated silica gel available from Albermarle Corp as XPO-2409 and containing about 12.01 wt. % Al TCB-1,2, 4-triclorobenzene TCE-1,1, 2, 2-tetrachloroethane TEoS-triethoxysilane (a group) THF-tetrahydrofuran TMS-trimethylsilyl TMoS-trimethoxysilane (a group) TPB-triphenylborane UV-ultraviolet VS-vinylsilane VTEoS-vinyltriethoxysilane

VTMoS-vinyltrimethoxysilane NMR Analyses : 1H NMR spectra were typically obtained on a 500 MHz Bruker AvanceS) spectrometer on a 5 mm quad probe on about 10 mg samples di- luted in 0.5 ml TCE-d2 at 120°C using a 90 degree pulse of 15 psec, a spec- tral width of 12.8 kHz, digital filtering, an acquisition time of 2.6 sec and a re- cycle delay of 30 sec. A total of 16 transients were acquired. Spectra were referenced to TCE-d2 at 5.928 ppm.

1H NMR spectra were also obtained on a 500 MHz Bruker AvanceS) spectrometer on a 5 mm probe on 40-45 mg samples diluted in 0.5 ml TCE-d2 at 120°C using a 90 degree pulse of 8. 6 p, sec, a spectral width of 7 kHz, digi- tal filtering, an acquisition time of 4.7 sec and a recycle delay of 30 sec. A total of 16-64 transients were acquired. Spectra were referenced to tce-d2 at 5.928 ppm.

The 13C NAAR spectra were typically obtained on a Varian@ 400 MHz Unity@ NMR spectrometer with a 10 mm BB probe at 120°C using typically 310 mg of sample dissolved in 3.1 ml total volume with TCB with an acquisi- tion time of 0.64 sec, a recycle delay time of 30 sec, about 19 lisec 90° pulse, a spectral width of 35 kHz, inverse gated Waltz 1H decoupling, 2808 tran- sients averaged.

Spectra were also obtained on a Bruker AvanceS) 500 MHz NMR spectrometer with a 10 mm quad probe at 120°C using 310 mg sample dis- solved in 3.1 ml total volume with 1,2, 4 trichlorobenzene with an acquisition time of 0.64 sec, a recycle delay time of 30 sec, a 15.5 psec 90° pulse, a spectral width of 29 kHz, digital filtering, inverse gated Waltz'H decoupling, 2767 transients averaged. Sometimes 60 mg of CrAcAc was added to the sample, although typically this was not done with Si containing polymers for fear the CrAcAc would promote crosslinking. If CrAcAc was used, the recycle delay was 5 sec and the total experiment time was cut in half. Spectra were referenced to the upfield TCB carbon at 127. 918 ppm. DEPT 135 spectra were collected on the same samples under similar conditions except that the recycle delay was typically 2 sec and the total experiment time was typically 30-90 min.

The 29Si NMR spectra were typically obtained on a Varian 400 MHz Unity@ NMR spectrometer with a 10 mm BB probe at 120°C using typically 310 mg of sample dissolved in 3.1 ml total volume with TCB with an acquis- tion time of 0.64 sec, a recycle delay time of 30 sec, about 12 µsec 90° pulse, a spectral width of 16 kHz, inverse gated Waltz'H decoupling, 2500 tran- sients averaged. Spectra were externally referenced to a sample of tet- ramethylsilane in TCB at 120°C as 0.0 ppm.

The NMR resonance assignments for Si related polymer structures quoted herein were determined by the 2D NMR techniques cosy, tocsy, hsqc, hsqc-tocsy and Irhmbc (the latter for 1H-29Si correlations).

For the polymer shown in the 1H NMR spectrum of Figure 1, 2D 1H-13C NMR experiments show that peak A is related to at least three different kinds of CH2 carbons. These were verified as CH2 in a 13C DEPT experiment. Also, peak A is related to at least three different Si containing structures, as verified by 1 H-29Si 2D NMR and 1 D 29Si NMR. Peak B is related to one CH carbon by 1H-13C 2D NMR and to 1 type of Si containing structure by H-Si 2D NMR and 29Si 1 D NMR. The chemical shifts are as follows : 1H NMR 13C NMR 29Si NMR Peak A 0.60 ppm 7.9, 11.2, 17 ppm 44-47 ppm (3 or more pks) Peak B 073 ppm 24.0 ppm 48 ppm For the nomenclature of the types and positions of various groups such as polymer branches in the NMR spectra, see World Patent Application 96/23010, which is hereby included by reference. For silyl ended branches, derived for example from the copolymerization of alkenyl-, allyl-or vinylsi- lanes, the nomenclature is xSBy wherein x is the carbon atom being referred to, with the carbon atom next to the silicon atom is 1, or if the silicon atom is bound directly to a methine carbon atom that carbon atom is"M", and y is the number of methylene groups between the silicon atom and a methine carbon atom (usually the branch point on the polymer chain). 13C NMR Chemical Shifts of Carbon Atoms Next to Si in Various Compounds Compound or Polymer MSB0 1SB1 1B2 1SB3 1SB4+ E/VTEoS 24. 0 16.9 7.9 11.7 11. 2 E/VTMoS 23. 4 16.0 6.8 10.3 9.8 1-oct-7-enylTEoS 11. 2 1-oct-7-enylTMoS 9. 8 E/ATMoS 15. 6 E/1-oct-7-enylTEoS 11. 2

Transition Metal Complexes The following transition metal complexes are used in the Examples :

Syntheses of the compounds similar to A, B and X through DD are found in previously incorporated US5880241, syntheses of compounds similar to C through G are in previously incorporated US5955555, syntheses of com- pound similar to H through P are found in previously incorporated U. S. Provi- sional Application Serial No. 60/294, 796 (filed May 31,2001) ; syntheses similar to compound are found in previously incorporated U. S. Patent Applica- tion Serial No. 09/871,100 (filed May 31,2001) ; and syntheses of compounds similar to Q through U and W are found in previously incorporated U. S. Patent Application Serial No. 09/871,099 (filed May 31,2001). The specific synthe- ses of B and V are described below.

Examples 1-3 In a drybox, separate stock solutions of A and MMAO-IP (Akzo Nobel, solvent removed in vacuo) were prepared in 5 mL of anhydrous chloroben- zene. For each polymerization aliquots of the A solution and MMAO solution were removed and placed in separate vials and the vials were diluted as nec- essary with chlorobenzene to adjust the volume of each solution to 2.5 mL.

The vial containing the A solution was then charged with 3 mL of VTMoS for each run. Anhydrous isooctane (142 mL) was cannulated into a dry steam- jacketed 600 mL autoclave under N2 followed by the MMAO-IP solution in chlorobenzene. A metal catalyst addition tube was charged with the < A/VTMoS solution and attached to the autoclave under N2. The reactor was then purged 3x with ethylene at >689 kPa to saturate the solvent with ethyl- ene and then heated to the reaction temperature. The ethylene pressure was then set to about 4.00-4. 07 MPa. The catalyst addition tube was pressurized with ethylene to 4.14 MPa. After achieving the desired temperature in the autoclave, the catalyst solution was pressure injected into the autoclave. The ethylene pressure in the autoclave rose to 4. 14 MPa and was maintained there throughout the reaction. The reactions were allowed to proceed for varying lengths of time based on the observed rate of ethylene uptake.

Polymer workups: The autoclave was depressurized and cooled to room temperature. Polymer of Example 1 was filtered and washed with methanol on the filter. Polymer of Example 2 was filtered and washed with acetone. Polymer of Example 3 was filtered and washed with hexanes.

Polymer of Example 1 was dried at 60°C for 24 h under vacuum in a vacuum oven. Polymers of Examples 2 and 3 were dried at RT in vacuo for 8 h and 50 h respectively. Branching and VTMoS content were determined by 1H NMR in d2-1, 1, 2, 2-tetrachloroethane at 120°C. The (CH30) 3Si- peaks come at approximately 3.58-3. 68 ppm downfield of tetramethylsilane. Results and other conditions are given in Table 1.

Table 1 Example 1 2 3 A (mmol) 0. 00052 0. 00052 0. 00078 MMAO-IP (mmol Al) 0.52 0.52 1.5 Reaction Temp (°C) 60 75 67.5 Reaction time (min) 120 60 40 Polymer Yield (g) 3.7 1. 1 2. 43 Incorporation of VTMoS (wt %) 0. 58 4.1 1.2 Productivity (kg polymer/g Ni) 121.2 36 53.1 H NMR Branching (CH3 per, 1000 CH2) 1 3. 1 12.3 4.2 Melt index (190°C, 2. 16 kg) no flow no flow no flow Example 4 The same autoclave and procedure were used as in Examples 1-3. A stock solution of B was prepared by dissolving 10 mg of Ni complex in 5 mL of chlorobenzene. VTMoS (3 mL) and isooctane (137 mL) were charged as a solution to the reactor via cannula followed by 0.354 g (0.691 mmol) of B (C6F5) 3 dissolved in 1 mL of chlorobenzene also by canula. The reaction was initiated by pressure injecting a 150 pl aliquot of the catalyst stock solu- tion diluted in 5 mL via the catalyst addition tube (0.0231 mmol Ni). Reaction conditions were 67. 5°C, 4.14 MPa ethylene. The reaction was run for about 10 min. The polymer was filtered and washed with 3 portions of anhydrous ether and then dried overnight at room temperature in vacuo. Polymer yield 1.06 g (0. 78 kg polymer/g Ni). Melt index (190°C, 2.16 kg): no flow. VTMoS content: 4. 06wt%.'H NMR branching (CH3 per 1000 CH2): 18. 9.

Example 5 A 600mL Parr@ reactor was heated under vacuum and was then al- lowed to cool under nitrogen. In a drybox, 15mL of vinyltrimethoxysilane and 135mL 2,2, 4-trimethylpentane were mixed in a 500mL RB flask. It was sealed using a rubber septa and was removed out of the drybox. The solution in the RB flask was transferred into the autoclave via cannula under positive nitro- gen pressure. In a drybox, 1. OmL 7.3wt% (in Al) MMAO heptane solution was dissolved in 3mL 2,2, 4-trimethylpentane in a scintillation vial. It was sealed with a rubber septum. The vial was taken out of the drybox. The solution was transferred via cannula into the autoclave under positive nitrogen pressure.

The autoclave was sealed and was pressured up to 690 kPa of nitrogen. Ni- trogen was vented. The pressuring/venting was repeated two more times. At about 35 kPa nitrogen, the autoclave was stirred at about 600 rpm. Ethylene pressure (-2. 07 MPa) was applied. The autoclave was placed in a preheated 80°C oil bath. In a drybox, 200mg 0.5wt% biphenyl solution of C was dis- solved in 5mL 1,2, 4-trichlorobenzene. The solution was transferred to an ad- dition cylinder. The cylinder was removed from the drybox and was attached to the reactor. Ethylene pressure (3.10 MPa) was applied to the cylinder to push the catalyst into the autoclave. The pressure of the reactor was ad- justed to 3.45 MPa and the temperature of the heating bath was adjusted to make the reaction temperature ca. 80°C. It was stirred at this temperature and pressure for 2h. Heating source was removed. Ethylene was vented to -69 kPa. The reactor was back filled with 2.07 MPa nitrogen and nitrogen was vented to about 69 kPa after brief stirring. The pressuring/venting was repeated two more times. The autoclave was brought into the drybox. Poly- mer was filtered, washed five times with hexanes and was dried in vacuo.

White polymer (17.18g) was obtained.'HNMR (TCE, 120°C) : 0.14 mole% VTMoS incorporation; 5. 7Me/1000CH2. GPC (TCB, 135°C) : Mw = 18, 243 ; Mn = 5, 386; P/D = 3.4.

Example 6 In a drybox, 10. 0mg of C was mixed with 15mL toluene in a 20mL vial.

To this mixture was added 0.714g silica gel (Akzo-Nobel 948 silica gel). The mixture was shaken for 30min. Solid was filtered, washed with 3X5mL tolu- ene and dried in vacuo. Blue-gray solid (0.676g) was obtained.

A 600mL Parr@ reactor was heated under vacuum and was then al- lowed to cool under nitrogen. In a drybox, 71.4mg of the silica supported C was placed in an addition tube. A Hoke@ cylinder containing 20mL of 2,2, 4- trimethylpentane was attached on the top of it. Then 110mL 2,2, 4- trimethylpentane, 20mL VTMoS and'1. OmL 7.3wt% (in Al) MMAO heptane solution were added to a 500mL RB flask. The flask was sealed with a rubber septa. Both the RB flask and the addition tube/Hoke@ cylinder were brought out of the drybox. The addition tube/Hoke@ cylinder was attached to the re- actor under positive nitrogen flow. Then the mixture in the RB flask was can- nulated to the reactor under positive nitrogen flow. The solution in the reactor was heated to 80°C, then, pressurized with 2.76 MPa ethylene. The sup- ported catalyst and 20mL of 2,2, 4-trimethylpentane were added from the Hokea cylinder/addition tube at 3.45 MPa of ethylene pressure. The reaction mixture was allowed to stir at 80°C under 3.45 MPa for 2h. Heating source was removed. Ethylene was vented. The reactor was back filled with 2.07 MPa nitrogen and was then vented. The pressuring/venting was repeated two more times. The reactor was brought into the drybox under nitrogen. Poly- mer was filtered, washed four times with pentane and was dried in vacuo.

White polymer (5.78g) was obtained.

Examples 7-21 The alkyl aluminum cocatalysts were purchased from commercial sources, PMAO-IP (3) (polymethylaluminoxane (PMAO-IP) from Akzo Nobel Inc. ; 12.7 wt% aluminum in toluene (0. 88 g/mL at 30°C)), or synthesized by literature methods, AIMe (2, 6-tBu4-Me (OC6H2)) 2 (1) ( (a) Shreve, A. P.; Mul- haupt, R.; Fultz, W. ;'Calabrese, J.; Robbins, W.; Ittel, S. D. Organometallics 1988,7, 409. (b) Healy, M. D.; Wierda, D. A.; Barron, A. R. Organometallics 1988,7, 2543], and (Al'Bu2 (OC6F5)) 2 (2) (Hendershot, D. G.; Kumar, R.; Bar- ber, M.; Oliver, J. P. Organometallics 1991, 10, 1917).

In a drybox, a glass insert was loaded with a combination of ligand and metal precursor or an isolated metal precatalyst and 2 mL of solvent. The solution was cooled to-30°C and a solid portion of aluminum catalyst (1 or 2) or solution of PMAO-IP (3,12. 8 wt % Al in toluene) was added followed by 4 mL of solvent and the solution was cooled to-30°C. The liquid monomer was added to the frozen solution followed by the remaining amount of solvent and then cooled to-30°C. The inserts were capped and placed in a rack and sealed in two plastic bags. Outside the drybox the rack was transferred to a pressure vessel and flushed with ethylene. The pressure vessel was pres- surized with ethylene and heated to the desired temperature and mechani- cally shaken for 18 h. The reaction solution was quenched with 30 mL of methanol and the polymer was isolated by filtration, rinsed with additional methanol and dried under vacuum. Other details of the polymerization condi- tions and products are given in Table 2.

Table 2 Ex. Catalyst AI (eq) Monomer solvent Temp Pres-Yield (g) Incorp mole M. W. (Mp, Mw, Mn, PDI) (mmol) sure % MPa 7 D (0. 01) 1 (100) VTMoS3mL p-xylene 80 °C 3. 45 5. 112 0. 06 8 D (0. 0014) 2 (714) VTMoS0. 5mL p-xylene 80°C 3. 45 3. 451 0. 02 7328, 8199, 3656, 1. 77 9 D (0. 0014) 2 (714) VTMoS 1. OmL p-xylene 80 °C 3. 45 2. 929 0. 01 6876, 7609, 3384, 2. 25 10 D (0. 0014) 1 (714) VTMoS 0. 5mL p-xylene 80 °C 3. 45 2. 683 0. 015 7127, 11470, 3045, 3. 77 11 D (0. 0014) 1 (714) VTMoS0. 5mL p-xylene 80°C 3. 45 5. 811 0. 05 7519, 15133, 3439, 4. 40 12 D (0. 0014) 1 (714) VTMoS0. 5mL p-xylene 100 °C 5. 17 6. 97 0. 02 4790, 19184, 2173, 3. 40 13 E (0. 002) 3 (2000) VTMoS1. OmL p-xylene 80°C 2. 07 5. 382 0. 023 4394, 11341, 2387, 4. 75 14 F (0. 002) 3 (2000) VTMoS 1. OmL p-xylene 80 °C 2. 07 0. 982 0. 03 15 G (0. 002) 3 (2000) VTMoS 1. OmL p-xylene 80 °C 2. 07 6. 309 0. 008 482, 964, 386, 2. 50 16 D (0. 0014) 1 (714) VTMoS 1. OmL 1, 2, 4-TCB 120 °C 5. 17 1. 63 0. 032 4895, 7524, 2410, 3. 12 17 D (0. 0014) 1 (714) VTEoS 1. OmL p-xylene 120 °C 5. 17 6. 981 0. 033 1959, 3314, 1043, 3. 13 18 D (0. 0014) 1 (714) VTEoS 1. OmL 1, 2, 4-TCB 120 °C 5. 17 0. 606 0. 12 19 D (0. 0014) 1 (714) VTEoS 1. OmL p-xylene 120 °C 5. 17 1. 184 0. 015 1804, 4242, 1076, 3. 94 20 D (0. 0014) 1 (714) ATMoS 1. OmL p-xylene 80 °C 3. 45 2. 377 0. 013 Insoluble 21 D (0. 0014) 1 (714) ATMoS 1. OmL p-xylene 120 °C 5. 17 4. 744 0. 014 aSolvent volume is 10 mL minus the volume of the monomer

Experiment 1 Benzyl-di-t-butylphosphine Di-f-butylchlorophosphine (75.0 g (0.415 mole)) and 0.5 mole of 12M solution of benzylmagnesium chloride in THF (200 ml) were refluxed under argon for 2 days. The reaction mixture was allowed to cool off to RT and an aqueous solution of ammonium chloride was added slowly. The organic phase was separated, and dried with magnesium sulfate. After removal of the solvent, the product was purified by distillation in vacuum. The yield of benzyl- di-t-butylphosphine was 94.3 g (96%) with b. p. 56-59°C/0. 1 mm. 31-P-NMR (CDC13) + 36.63 ppm. H NMR (CDCI3) 1.18 (s, 9H, Me3C), 1.20 (s, 9H, Me3C), 2.90 (d, 2JpH=2. 92Hz, P-CH2-Ph), 7. 1-7. 6 (m, 5H, aromatic protons).

Experiment 2 TMEDA Lithium Salt of Benzyldi-t-butvlphosphine Benzyidi-t-butylphosphine [5.0 g (0.021 mole)], 2.705 g (0.023 mole) of tetramethylethylenediamine (TMEDA), 20 ml of pentane and 15 ml of 1.7 M solution of tert-butyllithium in pentane were stirred at room temperature under nitrogen atmosphere for one day. After that the volume of the reaction mixture was decreased twice. The slow crystallization produced 3.8 g (51 % yield) of lithium salt of benzyl-di-tert-butylphosphine as the TMEDA adduct with m. p. at 98. 6°C. Elemental analysis for C21H40LiN2P. Calculated % P 8.65. Found % P 8. 74. 31P-NMR (THF-D8) 17.94 ppm. The structure was proved by X-ray analysis.

Experiment 3 Synthesis of V In a drybox, to a-30°C THF solution of t-butylisocyanate (0. 138g in 15mL THF) was added dropwise a-30°C solution of TMEDA lithium salt of benzyl-di-t-butylphosphine in THF (0.50g in 15mL THF). As the orange solu- tion warmed up to RT, solids formed. The thickened solution was stirred at RT overnight. To this solution was added 0. 189g ((allyl) NiCI) 2. The mixture was stirred overnight. The mixture was evaporated to dryness. The residue was extracted with toluene and was filtered through Celite0, followed by a toluene wash of the pad. The solution was evaporated to dryness and the

solid was dried in vacuo overnight. Dark red-brown solid (0.579g) was ob- tained.

Examples 22-58 General Polymerization Procedure In a drybox, a glass insert was loaded with the isolated Ni catalysts.

TCB, and optionally comonomers, were added to the glass insert. A Lewis acid cocatalyst (typically BPh3 or B (C6F5) 3) was often added to the solution.

The insert was then capped and sealed. Outside of the drybox, the tube was placed under ethylene and was shaken mechanically at the temperature listed in Table 3 for about 18 h. The resulting reaction mixture was mixed with methanol, filtered, repeatedly washed with methanol and the solid polymer dried in vacuo.

Standard conditions for most of these polymerizations are given in Ta- ble 3. Some other details of the polymerization processes are given in Tables 4-15, together with results on the polymeric products."Mole%"in these tables refers to the mole percent incorporation of that monomer into the polymers.

Table 3 Conditions for Ethylene Copolvmerizations In Glass Vials I 0. 005mmol catalyst, 7mL TCB, 3mL VTMoS, 80°C, 18h, 3. 45MPa ethyl- ene, 40eq BPh3 11 0. 00125mmol Catalyst H, 7mL TCB, 3mL VTMoS, 18h, 6.89MPa ethylene III 0. 005mmol catalyst, 7mL TCB, 3mL VTMoS, 80°C, 18h, 3.45MPa ethyl- ene, 40eq B (C6F5) 3 IV 0. 00125mmol Catalyst H, 9mL TCB, 1mL VTMoS or VTEoS, RT, 18h, 5.52MPa ethylene, 80 q B (C6F5) 3 V 0. 005mmol Catalyst, 9mL TCB, 1 mL VTMoS, RT, 18h, 5.52MPa ethylene, 40e B (C6F5) 3 V) 0. 002mmol Catalyst, 9mL TCB, 1mL VTMoS, RT, 18h, 5. 52MPa ethylene, 40eq B (C6F5) 3 Vil 0. 02mmol Catalyst, 5mL TCB, 5mL VTMoS, 60°C, 18h, 690kPa ethylene VIII 0. 005mmol Catalyst, 8mLTCB, 1mLVTMoS, 1. 0g norbornene, 60°C, 18h, 4.1 MPa ethylene Table 4 Condition I in Table 3 Ex Catalyst Yield #Me/ Mole% m. p. Mw/PDI (g) 1000CH2 VTMoS (°C) (#Hf*) 22 R 0.523 24 7.3 91 3, 773/4.2 66 (93. 4) 23 Q 3.465 16 3.9 102 (101.8) 7, 160/2. 3 24 H 10.663 25 2.1 110 (125.0) 12,075/4. 4 25 O 0.716 23 9.2 85 7,565/7. 1 63 (57. 0) Table 5 Condition II in Table 3

Ex T BPh3 Yield #Me/ Mole% m.p. Mw/PDI (°C) (equiv. ) (g) 1000CH2 VTMoS (°C) (AHf*) 26 60 0 2.829 24 4.0 118 (233.4) 4,496/2. 3 27 60 40 3. 853 23 4. 3 116 (239.5) 4, 982/2. 4 28 80 0 2.269 30 4.3 116 (90.3) 3,440/2. 1 29 80 40 2.522 23 2.6 116 (171.2) 7, 225/3. 4 30 100 0 2.727 30 2.2 108 2, 910/2.0 115 (177. 9) 31 100 40 2.602 40 3.8 108 3,596/2. 6 116 (165. 2) Table 6 Condition III in Table 3 Ex Catalyst Yield #Me/ Mole% m.p. Mw/PDI (g) 1000CH2 VTMoS (°C) (Hf) 32 V 0. 026 20 4. 7/ 33 U 0.691 12 2.8 102 (54.6) 8,118/8. 9 34 1. 689 27 3. 5* 105 (136.1) 5, 166/4. 6

* According to CNMR spectroscopy of the same copolymer, VTMoS incorpo- ration was 2. 51 mole % (2.32% IC, 0.19% EG).

Table 7 Condition IV in Table 3 Ex Monomer Yield #Me/ Mole% Mw/PDI (g) 1000CH2 VT (M) (E) oS 35 VTMoS 4. 306 5 0. 2 40, 133/3.7 36 VTEoS 1.992 4 0.3 71, 664/5.6 Table 8 Reaction Using 0. 00125mmol Catalyst O, 9mL TCB, 1mL VTMoS, RT, 18 h, 5.52MPa Ethylene, 80eg BPh3

Ex Yield #Me/ Mole% Mw/PDI (g) 1000CH2 VTMoS 37 0. 681 6 0. 2 156, 984/2.2 Table 9 Reaction Using 0. 00125mmol Catalyst H, 9mL TCB, 1mL VTMoS or VTEoS, 100°C, 18 h, 6.89MPa Ethylene, 80eg B C6E5) 3 Ex Monomer Yield #Me/ Mole% Mw/PDI (g) 1000CH2 VTMoS or VTEoS 38 VTMoS 3.028 10 0.4 21, 183/5.1 39 VTEoS 3. 242 10 0. 6 12, 475/3.6 Table 10 Reaction Using 0. 00125mmol Catalyst H, 7mL TCB, 1mL VTEoS and 2mL 1- hexene, 100°C, 18 h, 6.89MPa ethylene, 80eq B(C6F503 Ex Yield #Me/ Mole% Mole% Mw/PDI (g) 1000CH2 1-hexene VTEoS 40 0. 76 21 * 0. 9* 3. 4* 7, 663/3.2 * Based on 13CNMR Table 11 Reaction Using 0. 00125mmol Catalyst Q, 9mL TCB, 1mL VTMoS, 100°C, 18h, 6.89MPa Ethylene, 80eg BPh3 Ex Yield #Me/ Mole% Mw/PDI (g) 1000CH2 VTMoS 41 3. 25 29 0. 3 32, 800/4.5 Table 12 Reactions Using 0. 0005mmol Catalyst, 9mL TCB, 1mL VTMoS, RT, 18h, 5. 52MPa Ethylene Ex Catalyst B (C6F5) 3 BPh3 Yield #Me/ Mole% Mw/PDI (equiv.) (equiv. ) (g) 1000CH2 VTMoS 42 H 0 0 8.10 6 1.1 15, 700/2.7 43 H 80 0 8.04 3 0.2 67,800/8/0 44 H 0 80 7.47 6 0.8 57,000/7. 4 45 M 0 0 3.15 11 3.7 8,800/2. 5 46 M 0 80 4.48 8 1.1 113, 900/18.9

Table 13 Condition V in Table 3 Ex Catalyst Yield #Me/ Mole% Mw/PDI (g) 1000CH2 VTMoS 47 S 8.57 10 0.1 Not Soluble 48 P 2.24 17 0.04 50,500/37. 2 49 N 6. 01 26 1. 2 11, 000/6.1 Table 14 Condition VI in Table 3 Ex Catalyst Yield #Me/ Mole% Mw/PDI (g) 1000CH2 VTMoS 50 I 5.505 8 0.4 14,415/5. 5 51 J 15.117 9 0.8 23, 643/6.7 52 K 1.839 11 0.3 17,158/11. 6 53 L 4.746 12 0.8 5,588/4. 1 54 H 8.894 11 0.8 21, 868/3.7

Table 15 Condition Vil in Table 3 Ex Catalyst Yield #Me/ Mole% (g) 1000CH2 VTMoS 55 3. 206 21 10. 2 56 J 1. 114 18 6. 2 57 H 5. 837 21 9. 2 58 M 2. 583 18 7. 0

The following listing gives the data of a C NMR spectrum of the poly- mer made in Example 34 (see Table 6). The calibration is such that the TCB peak is at 127.918 ppm. The spectrum was run on a Bruker Avance@ 500 MHz spectrometer at 120°C using 317 mg of polymer dissolved in TCB to a total volume of 3.1 ml. In the listing below the designations the structures rep- resented by some of the peaks (last column) are found in Figure 2. Other designations are defined in previously incorporated US5880241. Index Frequency, Hz 8, ppm Intensity 1 19340. 297 153. 735 0. 34 V 2 17492. 873 139. 050 1. 5 F 3 17093. 461 135. 875 0. 31 4 17006. 227 135. 181 0. 79 5 16968. 494 134. 882 2. 46 6 16846. 947 133. 915 193. 71 7 16786.719 133.437 236. 8 8 16754. 234 133. 178 5. 14 9 16711. 967 132. 842 1. 23 10 16553. 945 131. 586 203. 19 TCB 11 16532. 863 131. 419 17. 71 12 16488. 236 131. 064 600 TCB 13 16460. 029 130. 840 13. 91 14 16435. 576 130. 645 25. 14 15 16407. 293 130. 421 561. 1 TCB 16 16369. 630 130. 121 6. 72 17 16189. 216 128. 687 5. 88 18 16092. 383 127. 918 528. 55 TCB 19 16059. 675 127. 657 5. 95 20 16008. 888 127. 254 2. 28 21 15808. 684 125. 662 0. 17 A 22 15549. 071 123. 599 0. 33 C 23 14968. 029 118. 980 0. 39 U 24 14368. 763 114. 216 1. 68 E 25 6345. 199 50. 438 6. 64 G 26 6315. 521 50. 202 1. 92 27 4718.032 37.503 1.99 αB 28 4622. 789 36. 746 0. 38 29 4379. 232 34. 810 0. 17 30 4345. 250 34. 540 0. 44 31 4284. 008 34. 053 0. 26 32 4259. 902 33. 862 1. 39 33 4178.984 33.219 1.23 MB1 34 4117. 910 32. 733 0. 2 35 4044. 209 32. 147 3. 08 3B6+, 3EOC 36 3813. 351 30. 312 7. 18 37 3769. 264 29.962 191.68 CH2's 38 3715. 886 29. 537 4. 95 39 3700. 814 29. 418 3. 02 40 3677. 321 29. 231 3. 91 41 3621. 997 28. 791 0. 72 42 3447.644 27.405 2.47 ßto branch 43 3432. 221 27. 283 0. 84 44 3363. 793 26. 739 0. 25 45 3059. 051 24. 316 0. 18 46 2944. 907 23. 409 1. 62 MSBo 47 2887. 730 22. 954 0. 73 48 2872. 384 22. 832 3. 48 2Bs"2EOC 49 2508.885 19.943 1.27 1 B1 50 1764. 188 14.023 3.66 1 1 EOC 51 1589. 083 12. 632 0. 26 52 1236. 953 9. 833 0. 37 1 SB4+

Examples 59-75 General Information Regarding Molecular Weight Analysis : GPC mo- lecular weights are reported versus polystyrene standards. Unless noted oth- erwise, GPC's were run with RI detection at a flow rate of 1 mL/min at 135°C with a run time of 30 min. Two columns were used: AT-806MS and WA/P/N 34200. A Waters Ri detector was used and the solvent was TCB with 5 grams of BHT per gallon. Dual UV/RI detection GPC was run in THF at RT using a Waters 2690 separation module with a Waters 2410 RI detector and a Waters 2487 dual absorbance detector. Two Shodex columns, KF-806M, were used along with one guard column, KF-G. In addition to GPC, molecular weight information was at times determined by 1H NMR spectroscopy (olefin end group analysis) and by melt index measurements (g/10 min at 190°C).

General Procedure for Ethylene Polymerizations and copolymeriza- tions : In a nitrogen-purged drybox, a glass insert was loaded with the nickel or palladium compound and, optionally, a Lewis acid (e. g., BPh3 or B (C6F5) 3) and borate (e. g., NaBAF or LiBArF) and any other specified cocatalysts.

Next, the solvent was added to the glass insert followed by the addition of any co-solvents and then comonomers. The insert was greased and capped. The glass insert was then loaded in a pressure tube inside the drybox. The pres- sure tube was then sealed, brought outside of the drybox, connected to the pressure reactor, placed under the desired ethylene pressure and shaken mechanically. After the stated reaction time, the ethylene pressure was re- leased and the glass insert was removed from the pressure tube. The poly- mer was precipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution, and optionally, approximately 1 mL of (EtO) 3Si (i-Bu) or (EtO) 4Si. The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum overnight. The polymer yield and characterization were then obtained.

13C NMR spectrum were run without Cr (acac) 3 unless specified other- wise.

Tables 16-21 gives the conditions of the polymerizations and informa- tion on the polyolefins obtained. Table 22 gives branching analyses (by 13C NMR) of polymers produced in several of these examples. The branching stated in Tables 22A and 22B is per 1000 methylene groups, but is not cor- rected for ends of chains.

Table 16 Terpolymerization of Ethylene (6.9 MPa), VTEoS 1 mL) and EGPEA (1 mL) at 120°C (8 mL p-Xylene, 204.8 mg B(C6F5)3, 177. 2 ma of NABAF, 18 h) Ex. Cmpd Yield VTEoS Acrylate M. W. Total (mmol) 9 Incorp. Incorp. Me Mol% Mol% 59 410'700. 36 ; 0. 14 IC Mp=2, 922 ; MW=13S467, 11. 9 (13C) 0. 22 EG (13Ca) Mn=1, 591 ; PDI=8. 47 ('3Ca) al3 C NMR spectrum was run with Cr (acac) 3 present. According to'H NMR spectroscopy of the same copolymer, EGPEA incorp. is 1.4% (0. 49% IC, 0. 91% EG) and VTEoS incorp. is 0.43% (0.13% IC, 0.14% EB, 0. 16% EG).

Table 17 Copolymerization of Ethylene and VTEoS or VTMoS at 60°C [102. 4 ma B C6F5)3, 18 h Ex. Cmpd Comon-Press Solvent (s) Yield VTEoS/VTMoS M. W. Total (mmol) omer. ML g Incorp. Me mL MPa Mol% 60 X VTEoS 4. 1 p-Xylene 5. 54 1. 63 Mp=34, 515 ; 12. 9 1 8. 5 (13C) MW=57, 305 ; (13C) Ethyl Acetate Mn=17, 310 ; 0. 5 PDI=3. 31 61 X VTEoS 1. 0 p-Xylene 3. 88 3. 39 Mp=24, 226 ; 28. 7 1 8 (13C) Mu=31, 963 ; (13C) Ethyl Acetate Mn=12, 963 ; 1 PDI=2. 47 62 W VTMoS 5. 5 Isooctan 0. 41 1. 80 Mn ('H) = 4. 9 1 9 (1 H) 11, 260 (1H) 63 X VTMoS 5. 5 p-Xylene >3. 49 1. 46 Mn ('H) = 12. 9 1. 9 b (1H) No olefins (1H) 64 Y VTMoS 5. 5 p-Xylene >0. 25 13. 59 Mn ('H) = 32. 9 1 9 b (1H) No olefins (1H) 65 Z VTMoS 5. 5 p-Xylene >0. 08 0. 05 Mn ('H) = 3. 9 1 9 b ('H) No olefins ('H) 66 W VTMoS 5. 5 p-Xylene 0. 39 1. 29 Mn (l H) = 3. 5 u 1 9 (H) 8, 780 (H) r 67 DD VTEoS 4. 1 p-Xylene 1. 72 0. 19 Mp=59, 937 ; 112. 4 1 9 (13C) M, =56, 187 ; (13C) Mn=29, 531 ; PDI=1. 90

'For the C NMR spectrum run with Cr (acac) 3 : 5.43 mole% VTEoS incorporation; 19.2 Total Me. For the'H NMR spectrum: 1.9 mole% VTEoS incorporation; 35-45% of Si (OEt) 3 groups are incorporated in-chain and the remainder are located at the ends of branches or at the ends of chains; 14.6 Total Me; Mn = 18,150. From the 29Si NMR spectrum: 29-35% of Si (OEt) 3 groups are incorporated in-chain and the remainder are located at the ends of branches or at the ends of chains. Only a fraction of the polymer was isolated and weighed.

The 13C NMR analysis of the polymer of Example 61 is detailed in the table immediately below : Index Frequency, Hz Frequency, ppm intensity Peak assignment 1 7360. 012 58. 504 4. 36 CH2's of RSiOEt3, EtOH 2 7339.097 58. 338 7. 27 CH2 s of RSiOEt3, EtOH 3 5084. 703 40. 418 0. 47 4 4992. 975 39. 689 0. 40 MB2 5 4804. 840 38. 193 1.05 MB3+ 6 4781.408 38. 007 0. 80 MB3+ 7 4719. 437 37. 515 6. 48 B 8 4668. 750 37. 112 0. 96 B 9 4377. 204 34.794 0.69 10 4346. 790 34. 552 3. 86 B3+ 11 4308. 405 34. 247 0. 50 12 4285. 451 34. 065 1. 06 13 4269.436 33.938 1.16 MB1 14 4239.156 33.697 0.93 15 4180. 149 33.228 3.60 MB 16 4109. 614 32. 667 0. 27 3B5 17 4045.341 32.156 0.72 3B6+, 3EOC 18 3832.184 30.462 7. 24 19 3818. 750 30.355 11.43 CH2's 20 3770.353 29. 970 162. 79 CH2's 21 3716. 071 29. 539 1. 22 CH2's 22 3683. 974 29. 284 1. 81 CH2's 23 3498. 051 27. 806 0. 81 B2+ 24 3448.654 27.413 7. 47 B2+ 25 3432. 628 27. 286 5. 39 B2+ 26 3392.604 26. 968 0. 64 B2+ 27 3362. 671 26. 730 0.52 B2+ 28 3093. 992 24. 594 0. 20 29 3013. 120 23. 951 0. 76 MSBo 30 2984. 014 23.720 0.25 2SB4 (tent) 31 2937. 068 23.347 0. 33 2B4 32 2915.681 23.177 0. 56 2SB5+ (tent) 33 2873. 521 22. 841 0. 95 2Bs+ 34 2594. 025 20. 620 0. 31 2SB3 (tent) 35 2554. 888 20. 309 0. 44 2B3 36 2508.997 19. 944 3. 92 37 2330. 085 18.522 13. 12 CH3's of RSiOEt3, EtOH 38 2129. 444 16.927 0.50 1SB1 39 1832.811 14.569 0.35 1B3 40 1765.824 14. 036 1.06 1B4+, 1EOC 41 1466.504 11.657 0.40 1 SB3 42 1411. 958 11. 224 0.73 1SB4+, 1B2 43 1001.326 7.96 0.51 1SB2 Table 18 Terpolymerization of Ethylene (1. 03 MPa), VTMoS (1 mL), and 1-Hexene (1 mU at 60 °C (102. 4 ma B(C6F5)3, 18h Ex. Cmpd Solvent (s) Yield VTMoS M. W. Total (mmol) ML g Incorp. Me Mot% 68Xp-Xy ! ene1. 876'43Mn ('H) = 15, 650 47. 7 MHz 69 X p-Xylene 326 4. 59 Mn ('H) = 20, 400 57. 9 7 ('H) H) Ethyl Acetate 1

Table 19 Terpolymerization of Ethylene (1. 0 MPa), VTMoS (1 mL), and NBFOH (2 mL) at 60°C (102. 4 mg B(C6F5)3, 18 h NBFOH (exo)

Ex. Cmpd Solvent (s) Yield VTMoS NBFOH M. W. Total (mmol) mL g incorp. Incorp. Me Mol% Mol% 70 ! ene 0. 47 2. 97 0. 03 Mn (1 H) = 3, 160 15. 2 7 (C) (C) 2. 56 2. 56 IC&EB 0. 41 EG a1H NMR analysis of the same copolymer gives 0.49% NBFOH incorp. and 4. 84% VTMoS incorp. (3. 96% IC, 0.45% EB, 0.43% EG) Table 20 Copolymerization of Ethylene (2.1 MPa) and VTEoS (1 mL) at 120°C [102 4 mg B(C6F5)3, 18 h] Ex Cmpd Solvent (s) Yield VTEoS M. W. Total . (mmol) mL g Incorp. Me Mol% 71 AA p-Xylene 8 1. 51 2. 30 Mp=8, 875 ; Mw=10, 949 ; 82. 0 Ethyl Acetate 1 (13C) Mn=5, 108 ; PDI=2. 14 (13C) 72 BB p-Xylene 8 0. 86 0. 98 Mp=34, 661 ; Mw=40, 509 ; 129. 9 Ethyl Acetate 1 (13C) Mn=18, 431 ; PDI=2. 20 (13C) 73 Y p-Xylene 8 0. 92 2. 41 Mp=12, 132 ; Mw=26, 986 ; 111. 8 Ethyl Acetate 1 (13C) Mn=8, 100 ; PDI=3. 33 (13c) 74 CC p-Xylene 8 2. 48 1. 42 Mp=18, 367 ; MW=19, 846 ; 76. 3 Ethyl Acetate 1 (13C) Mn=9, 123 ; PDI=2. 18 (13C)

Table 21 Copolymerization of Ethylene (3.5 MPa) and VTMoS (10 mL) at 90°C [102. 4 mg B(C6F5)3, 18 h] Ex. Cmpd Solvent (s) Yield VTMoS M. W. Total (mmol) mL 9 Incorp. Me Mol% 75 CC None 0. 18 31. 95 Mn ('H) = 7, 940 36. 8 ('H) ('H) Table 22A

13C NMR Branching Analysis for VTMoS and VTEoS Copolymers Ex. Total Me Me Et Pr Bu Hex+ & Am+ & eoc Bu+ & eoc eoc 59 11. 9 3. 0 1. 4 0. 2 0. 3 6. 5 5. 9 7. 3 25. 2% 11.6% 2.0% 2.3% 54.6% 49.4% 61. 2% 60 12.9 10. 4 O. Oa 0.4 1. 0 6.1 1.7 2.2 80.3% 2.8% 8. 1 % 47.0% 13.2% 16. 9% 61 28.7 20.8 2.1 1.0 2.7 2.3 3.8 4.8 72. 4% 7.3% 3.5% 9.2% 8. 1% 13.2% 16. 9% 67 112. 4 38. 4 26.5 2.5 8. 5 25.8 30.0 45.0 34.2% 23.6% 2.2% 7.6% 22.9% 26.7% 40. 0% 70 15.2 4. 9 1. 3 0.4 5.6 5.8 7.2 8.6 32. 1 % 8.5% 2.6% 36.8% 38.0% 47.4% 56. 7% 71 82.0 44.6 13.0 3.7 4.1 10.2 13.2 20. 7 54. 4% 15.8% 4.6% 5. 0% 12.5% 16. 0% 25. 3% 72 129.9 78.0 19.5 4.1 6.4 14.1 19.1 28.3 60. 0% 15.0% 3.2% 4.9% 10. 8% 14.7% 21. 8% 73 111.8 61.5 19.3 4.3 7.7 12.3 14.5 26.7 55.0% 17.2% 3.9% 6.9% 11.0% 13.0% 23. 9% 74 76.3 44.5 11.9 3.3 4.1 8.4 10.3 16.5 58. 4% 15. 7% 4. 4% 5. 4% 11. 0% 13. 5% 21. 6% aEt branching peak under n =4+ Si branching peak. b1B1 = 18.0%, and 1B2 = 37.3% Table 22B Analysis of the Spacing (n) between Si and the Copolymer Backbone for VTMoS and VTEoS Copolymers Ex. n=0, % n=1, % n=2, % n=3, % n=4+, % 59 50. 0 12. 5 0. 0 0. 0 37.5 60 40.0 13.3 13.3 6.7 26. 7 61 21.6 20.9 20.2 12.6 24.6 70 87.5 8. 3 0. 0 0.0 4.2 73 25.0 Nda 25. 0 25. 0 25.0 74 50.0 12. 5 12. 5 12. 5 12. 5

Nd : Not detected.

Example 76 Copolymerization of Propylene with VTEoS A 600 mL autoclave was charged with 100 mL of toluene, 2 mL of MMAO (3M) and-480 kPa of propylene at RT. Then 10 mL of toluene solu- tion containing 0. 0169g (0.01 mmol) of X, 0. 6041g (1. 18 mmol) of tris (pentafluorophenyl) borane and 5 mL of VTEoS were transferred to the re- actor. The autoclave was maintained at a pressure of 460-480 kPa with pro- pylene and stirred for one h. The propylene was vented and the solution with some sticky material was rotary evaporated to yield a tan color powder which

was rinsed with ether, methylene chloride and ethanol. copolymer (2.45 g) was collected. 1HNMR (TCE-d2, 120°C) : 3.6 (q, 6, CH20), 1.22 (s, 1, CH), 1.5 (t, 9H, CH3), 0.93 (br, 2H).

Example 77 Copolymerization of Propylene with VTEoS A 600 mL autoclave was charged with 100 mL of toluene, 2 mL of MMAO (3M) and-480 kPa of propylene at RT. Then 10 mL of toluene solu- tion containing 0.0169g (0.01 mmol) of X, 0. 6041g (1. 18 mmol) of tris (pentafluorophenyl) borane and 0.5 mL of VTEoS was transferred to the reactor. The autoclave was maintained at a pressure of 460-480 kPa with propylene and stirred for one h. The propylene was vented and the solution with some sticky material was rotary evaporated to yield a tan color powder which was rinsed with ether, methylene chloride and ethanol. Brown powder product (1.02 g) was collected.

Examples 78-79 Terpolymerizations of Ethylene, VTMoS and VTEoS Glass vials (50 mL) were charged with 0.001 mmol of catalyst, 0. 1024g (0.2 mmol) of tris (pentafluorophenyl)-borane, 3 mL of cyclohexane, 1 ml of VTMoS (6.54 mmol) and 1 ml of VTEoS (4. 74 mmol). The vials were placed into a pressure tube, sealed and removed from the dry box. The pressure tube was connected to a high pressure ethylene shaker reaction unit and the polymerization was carried out at 50°C and 6.9 MPa ethylene for 18 h. After the reaction, the reaction mixture was worked up by pumping under high vac- uum to remove all the volatile materials and then washed with dry methanol.

Product details are given in Table 23. It was observed during characterization and manipulation of the polymer that the NMR signals of the two incorporated vinylsilanes generally reflected their relative concentrations in the monomer mixture. However during purification and workup, the intensity of the trimeth- oxysilyl group decreased relative to that of the triethoxysilyl group.

Table 23 Ex. Catalyst Polymer (g) 78 x 5. 8821 79 1 0. 717

Examples 80-86 Terpolymerizations of Ethylene with VTMoS and Non-silane vinyl monomers Glass vials (50 mL experiments) were charged with 0.001 mmol of J, 0. 1024g (0.2 mmol) of tris (pentafluorophenyl)-borane, 3 mL cyclohexane, 1 ml of vinyl monomer (see table below) and 1 ml of VTEoS. The vials were placed into a pressure tube, sealed and removed from the dry box. The pres- sure tube was connected to a high pressure ethylene shaker reaction unit and the polymerization was carried out at 50°C and 6.9 MPa ethylene for 18 h.

After the polymerization, the reaction mixture was worked up by pumping un- der high vacuum to remove all the volatile materials and then washing with dry methanol. Results are given in Table 24.

Table 24 Ex. No. Termonomer Polymer Product. Mw, PDI VTEoS Termon. yield KgPE/gNi Incorp Incorp (g) (%) (%) 80 E-10-U 1. 543 28. 3 9411 1. 02 0. 43 5. 16 81 Cyclopentene 6. 881 138 24010 0. 41 ND 4. 47 82 1-hexene 2. 974 32. 3 6916-0. 3 ND 6. 08 83 TMS-acrylate 0. 267 1. 22 1809 0. 73 2-3 2. 39 84 MA 0. 328 1. 38 2408 0. 72 2. 23 2. 54 85 EGPEA 0. 196 0. 86 7076 ND ND 4. 28 86 dicyclo-7. 65 13 371249 0. 12 4. 85 pentadiene 4. 469 Examples 87-90 and Comparative Examples A-D General Information Regarding Molecular Weight Analysis

GPC molecular weights are reported versus polystyrene standards.

Unless noted otherwise, GPC's were run with RI detection at a flow rate of 1 mL/min at 135°C with a run time of 30 min. Two columns were used: AT- 806MS and WA/P/N 34200. A Waters@ RI detector was used and the solvent was TCB with 5 grams of BHT per gallon. Dual UV/RI detection GPC was run in THF at rt using a Waters@ 2690 separation module with a Waters@ 2410 RI detector and a Waters@ 2487 dual absorbance detector. Two Shodex0 columns, KF-806M, were used along with one guard column, KF-G. In addi- tion to GPC, molecular weight information was at times determined by 1H NMR spectroscopy (olefin end group analysis) and by melt index measure- ments (g/10 min at 190°C).

General Procedure for Ethylene Polymerizations and Copolymerizations In a nitrogen-purged drybox, a glass insert was loaded with the speci- fied amount of B (C6F5) 3. Next, the solvent was added to the glass insert fol- lowed by the addition of any co-solvents and then comonomers. Finally, the nickel compound dissolved in 0.4 mL of Et20 was added to the glass insert via syringe. The same standard solution of the nickel complex was used for all of the entries in each table below. The insert was greased and capped. The glass insert was then loaded in a pressure tube inside the drybox. The glass inserts for all of the entries in each table below were loaded inside the same pressure tube. The pressure tube was then sealed, brought outside of the drybox, connected to the pressure reactor, placed under the desired ethylene pressure and shaken mechanically. After the stated reaction time, the ethyl- ene pressure was released and the glass insert was removed from the pres- sure tube. The polymer was precipitated by the addition of MeOH (-20 mL).

A small amount of triethylamine was added to the solution, and optionally, ap- proximately 1 mL of (EtO) 3Si (i-Bu) or (EtO) 4Si. The polymer was then col- lected on a frit and rinsed with MeOH. The polymer was transferred to a pre- weighed vial and dried under vacuum overnight. The polymer yield and char- acterization were then obtained.

13C NMR spectra for any Si-containing copolymer were run without Cr (acac) 3 unless specified otherwise. 13C NMR spectra for any homopolymer of ethylene were run in the presence of Cr (acac) 3. For methods for NMR analysis for branching and interpretations of those results see previously in- corporated US5880241, which is hereby included by reference.

Polymerization conditions and results of the polymerizations are found in Tables 25-28.

Table 25 Copolymerization of Ethylene (4. 1 MPa) at 60°C with X (0. 0001 mmol) (10 mL p-Xylene, 102.4 mg B(C6F5)3, 18 h) Ex. Comonomer or Additive Yield Comon M. W. Total 1. 7 mmol G Incorp. Me Mol% 87 VTMoS 0. 92 0. 78 MW=297564 ; 8. 7 ('H) Mon--13, 613 87a ATMoS 0. 21 0. 60 MW=22, 495 ; 8 8 (1H) Mn=10, 711 1-Docos-21-enyl-TEoS 1. 44 0. 0 MW=86, 456, Nd Mn=37, 394

Table 26 Conolymerization of Ethylene (4. 1 MPa) at 60°C with A (0. 0001 mmol) (10 mL ,-Xylene, 102.4 mg B(C6F5)3, 18 h) Ex. Comonomer or Additive Yield Comon. M. W. Total 1. 7 mmol G incorp. Me Mol% 88a ATMoS 0. 17 0. 38 MW=92, 565 ; 8. 0 ('H) Mn=14, 298 88 VTMoS 1. 86 0. 70 Mw=85, 725 ; 8. 9 ('H) Mn=28, 907 B 1-Oct-7-enyl-TMoS 0. 48 2. 59 Mu=58, 766 ; 13. 9 ('H) Mn=13, 745

Table 27 Copolymerization of Ethylene (4.1 MPa) at 60°C with X (0.0002 mmol) (10 mL p-xylene, 102.4 mg B(C6F5)3, 18 h) Ex. Comonomer or Additive Yield Comon. M. W. Total 3. 4 mmol ! incorp. Me Mou% 89a ATMoS 0. 64 0. 68 ('H) M=39, 015 ; 8. 5 ('H) Mn=17, 278 C 7-Oct-1-enyl-TMoS 1. 40 0. 22 ('H) MW=60, 351 ; 8. 7 ('H) Mi 30, 271 89 VTMoS 3. 15 1. 07 ('H) Mw=54, 557 ; 9. 5 ('H) Mn=22, 577 Table 28 Copolymerization of Ethvlene (41 MPa) at 60°C with X (0.0002 mmol) (10 mL p-Xvlene, 102. 4 mg B(C6F5)3, 18 h Ex. Comonomer or Additive Yield Comon. M. W. Total 3. 4 mmol g Incorp. Me Moi% 90 VTMoS 3. 03 1. 1 MW=38o599 ; 9. 9 (tH) Mn=14, 176 90a ATMoS 0. 66 0. 7 MW=32, 321 ; 9. 9 ('H) Mn=15, 075 D 1-Oct-7-enyl-TMoS 0. 89 0. 6 MW=24, 776 ; 9 4 (1H) Mn=13, 222

Examples 91-97 The general procedures described above for Example 22-58 were used in these examples. The conditions were as described in Table 3 under Con- dition VIII. Results are given in Table 29.

Table 29 Condition VIII in Table 3 Ex Catalyst B (C6F5) 3 Yield Mole% Mole% (equiv.) (9) Norbor-VTMoS nene 91 S 40 2. 839 1. 2 1. 3 92 T 40 0. 604 1. 0 0. 4 93 O 0 0. 458 2. 3 2. 9 94 J 0 0. 610 35. 9 1. 0 95 N 0 0. 969 30. 7 1. 6 96 M 0 0. 917 83. 4 2. 0 97 Q 0 5. 421 7. 5 1. 4

Examples 98-101 For polymerization procedure and method for measuring molecular weight, see Examples 59-75. Results are given in Tables 30 and 31.

Table 30 Copolymerization of Ethylene (1. 0 MPa) and VTEoS (1 mL) at 60°C with Cmpd X (0.001 mmol) (102. 4 mg B(C6F5)3, 18 h

Ex Solvent (s) Yield VTEoS M. W. Solubility in mi Total mL g Incorp. TCB at 120 °C Me Mol% 98 p-Xylene 3. 88 3. 39 Mp=24, 226 ; Soluble 1. 2 39. 4 8 (13C) MW=31, 963 ; (13C) Ethyl Acetate Mn=12, 963 ; 1 PDI=2. 47 99 p-Xylene 2. 84 Nd Mp=24, 382 ; insoluble No Nd 9 Mw=37, 675 ; Flow Mn=12, 210 ; PDI=3. 09 Nd: Not determined.

Table 31 Copolymerization of Ethylene (2. 1 MPa) and VTMoS (1 mL) at 90°C with Cmpd X (0. 01 mmol) (102.4 mg B(C6F5)3, 18 h Ex Solvent (s) Yield VTMoS Mn ('H) Solubility in MI Total mL g Incorp. TCB at 120 °C Me Mol% 100 p-Xylene 4. 85 8. 42 14, 980 Insoluble No 57. 8 5 ('H) Flow (1H) 101 i-BuTMoS 6. 97 8. 41 17, 160 Soluble 85 53. 8 Me2CHCH2Si ('H) (1 H) - (OMe) 3 5 The 13C NMR of the polymer of Example 101 is given in Table 32.

Table 32 Index Frequency, Hz Frequency, ppm Intensity Peak assignment 6314.146 50. 191 10. 43 CH3 of RSiOMe3, CH30H 2 6282.099 49.936 16. 41 CH3 of RSiOMes, CH30H 3 5056. 362 40. 193 0. 57 4 4963. 028 39. 451 0. 39 MB2 5 4774. 828 37. 955 1. 78 MB3+ 6 4742. 194 37. 695 1. 39 MB3+ 7 4690. 522 37. 285 6. 91 B 8 4637.857 36.866 2.07 B1 9 4317. 338 34. 318 6. 34 B3+ 10 4257. 767 33. 845 1. 93 11 4235. 311 33. 666 1. 83 12 4192.635 33.327 1.74 MB1 13 4150. 306 32.991 3.63 MB 14 4078. 868 32. 423 0.31 3Bs 15 4014. 595 31. 912 0. 89 3Bs+, 3EOC 16 3961. 837 31. 492 0. 42 17 3801. 748 30. 220 10. 17 CH2's 18 3788. 414 30. 114 13. 30 CH2's 19 3740.868 29.736 78.25 CH2's 20 3648. 688 29.003 3.66 CH2's 21 3467. 381 27.562 2. 05 B2+ 22 3418. 749 27.175 8. 54 B2+ 23 3402. 893 27. 049 8.40 B2+ 24 3333. 715 26. 500 1. 80 B2+ 25 3080. 475 24. 487 0. 49 26 2917. 079 23. 188 1. 80 MSBo, 2B4 27 2858.379 22. 721 1.52 2SBs+ (tent) 28 2842. 526 22.595 1. 53 2Bs+ 29 2535. 711 20. 156 0.96 2SB3(tent), 2B3 30 2475. 923 19. 681 4. 60 1 B 31 1929.196 15.335 1.33 1SB1 32 1799. 730 14.306 0.49 1 B3 33 1734.624 13. 788 1. 55 1 B4+, 1 EOC 34 1372. 371 10. 909 0.64 1B2 35 1259. 282 10. 010 0. 75 1 SB3 36 1206.399 9.590 1.36 1SB4+ 37 798.652 6.348 0.76 1SB2

Example 102 Synthesis of Complex B In the dry box a 500 mL oven-dried Schienk flask was charged with 3.19 g (7.67 mmol) of ligand EE (see previously incorporated US5880241), 200 mL of anhydrous pentane, and a magnetic stir bar. In a separate oven-dried 100

mL round bottom flask 3.0 g of Ni (CH2SiMe3) 2 (py) 2 (7.67 mmol, Carmona, E.; Gonzalez, F.; Poveda, M. L.; Atwood, J. L.; Rogers, R. D., Journal of the Chemical Society, Dalton Transactions (1981) 777-782) was dissolved in 45 mL of pentane along with 1 mL of anhydrous pyridine to stabilize the complex.

Both flasks were septum capped and removed from the dry box and placed under dry N2. The ligand/pentane slurry was cooled to-18°C in an ice/acetone bath. The Ni complex was added to the ligand/pentane slurry via cannula over 10 minutes at-18°C. The resulting intensely blue solution was allowed to stir at-11 °C to-18°C for 4 hours. After 4 hours the solvent was removed under vacuum and the blue crystalline solid was collected and weighed. Net wt. 4. 8 g. (96.6% yield). 1H NMR (C6D6, 500 MHzX ppm downfield of tetramethylsilane) : 7.65 (d, 2H, An-H); 7.02 (s, 4H, ArH); 6.83 (d, 2H, An-H); 6.58 (triplet, 2H, An-H); 2.38 (s, 12H, o-ArCH3) ; 2.33 (s, 6H, p- ArCH3) ; 1.88 (bs, 4H, NiCH2) ; 0.20 (s, 18H,-SiMe3).

Examples 103-112 and Comparative Examples D-E General Procedure for Ethylene Copolymerizations of Tables 33 and 34 In a nitrogen-purged drybox, a glass insert with a gas inlet was loaded with the specified amounts of B, B (C6F5) 3, NaBAF or LiB (C6F5) 4'2. 5Et20, co- monomer and p-xylene. The B (C6F5) 3 was the first ingredient added to all ex- periments and was added as a standard solution in THF. The THF was al- lowed to evaporate prior to the addition of the other reactants. The NaBAF or LiB (C6F5) 4 2. 5 Et20 was added as a standard solution in Et20, and B was added as a standard solution in a cyclopentene/Et20 mixture. The order of addition was (1) B (C6F5) 3, (2) p-xylene, (3) comonomer, (4) NaBAF or

LiB (C6F5) 42. 5Et2O, and (5) B. For entries 105-I of Table 33, the concentra- tions were 0.005 mmol of B per 0.2 mL cyclopentene/Et2O (6.25% solution of cyclopentene in Et20) and 0.005 mmol of NaBAF per 0.2 mL Et20. For en- tries 109-J of Table 33, the concentrations were 0.01 mmol of B per 0.4 mL cyclopentene/Et20 (16.7% solution of cyclopentene in Et20) and 0.01 mmol NaBAF per 0.4 mL Et20. For entries 110-K of Table 34, the concentrations were 0.0005 mmol of B per 0.5 mL of cyclopentene/Et20 (1.5% solution of cy- clopentene in Et20) and 0.0005 mmol of LiB (C6F5) 4 2. 5 Et20 per 0.2 mL Et20.

For entry 114 of Table 34, the concentrations were 0.001 mmol of B per 0.2 mL of cyclopentene/Et20 solution (8.3% solution of cyclopentene in Et2O) and 0.001 mmol of LiB (C6F5) 4 2. 5 Et20 per 0.2 mL Et20. The insert was greased and capped. The glass insert was then loaded in a pressure tube inside the drybox. The pressure tube was then sealed, brought outside of the drybox, connected to the pressure reactor, placed under the desired ethylene pres- sure and shaken mechanically. After the stated reaction time, the ethylene pressure was released and the glass insert was removed from the pressure tube. The polymer was precipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution. The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR spectra were run without Cr (acac) 3.

Table 33 Comparative VTMoS. VTEoS, ATMoS, ATEoS, and 7-Oct-1-enyl- trimethoxysilane Copolymerizations with Ethylene (4. 1 MPa at 60°C with B (10 mL Total Volume of p-Xylene + Comonomer, 1 equiv B(C6F5)3, 1 equiv

NaBAF. 18 h) Ex. mmol Comonomer Yield Comon. M. W. Mi/. total B 17 mmol g incorp. a Sol. d Mea Mol% 103 0. 005 VTEoS 6. 30 5. 7 Mw 17, 941 ; Mn=6, 595 ; High 34. 0 3. 6 mL, 3, 400 equiv PDI=2. 31 S 104 0. 005 VTMoS 3. 74 4. 8 Mw=26, 270 ; Mn=8, 410 ; 1. 25/ 26. 0 2. 6 mL, 3, 400 equiv PDI=3. 12 S 105 0. 005 ATEoS 0---- 3. 9 mL, 3, 400 equiv 106 0. 005 ATMoS 4. 81 4. 0 Mu=269863 ; Mu=9, 449 ; 2. 95/ 14. 4 2. 9 mL, 3, 400 equiv PDI=2. 84 s D 0. 005 7-Oct-1-enylTMoS 0. 30 1. 9-MW=397689 ; nd/19. 4 4. 3 mL, 3, 400 equiv ('H) Mn=18, 332 ; PDI=2. 16 P ('H) 107 0. 01 ATEoS 0. 98 4. 1 M, =16, 562 ; Mn=8, 126 ; nd/12. 6 3. 9 mL, 340 equiv PDI=2. 04 P 108 0. 01 7-Oct-1-enyITMoS 0. 74 1. 7 Mi 72, 231 ; nd/8. 1 4. 3 mL, 340 equiv Mn=23, 255 ; PDI=3. 147 P

nd: Not determined. aData obtained from C NMR unless specified otherwise. From H NMR, 0% n=0. cFlow was too fast to measure. dSol. : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g., some insoluble material present.

Table 34 Comparative VTMoS, VTEoS. ATMoS, ATEoS, and 7-Oct-1-enyl- trimethoxysilane Copolymerizations with Ethylene (4. 1 MPa) at 60°C with B (10 mL Total V of p-Xylene + Comonomer, 2.6 mq B (C6_5) 1 equiv

LiB(C6F5o)4, 18 h) mmol B Comonomer Yield Comon. M. W. MI/Total mg B (C6F5) 3 6. 5 mmol g Incorp. Sol. Me Mol% 109 0. 0005 mmol VTEoS 3. 82 1. 9 MW=44} 699 ; 4. 1/ 12. 2 2. 6 mg 1. 4 mon=20, 089 ; S 13, 100 equiv PDI=2. 23 110 0. 0005 mmol VTMoS 3. 81 1. 9 Mi 44, 482 ; 5. 3/ 15. 5 2. 6 mg 1. 0 mL Mn=18, 145 ; S 13, 100 equiv PDI=2. 45 111 0. 0005 mmol ATEoS 0. 02---- 2. 6 mg 1. 5 mL 13, 100 equiv 112 0. 0005 mmol ATMoS 1. 00 1. 2 Mi 66, 696 ; 0. 1/ 10. 5 2. 6 mg 1. 1 mL Mn=22, 494 ; S 13, 100 equiv PDI=2. 96 E 0. 0005 mmol 7-Oct-1-enylTMoS 0-- 2. 6 mg 1. 7 mL 13, 100 equiv 113 0. 001 mmol ATMoS 7. 22 1. 3 Mu=51, 346 ; No 11. 3 5. 2 mg 1. 1 mL Mn=9, 893 ; flow/ 6, 500 equiv PDI=5. 19 P aData obtained from C NMR unless specified otherwise. So). : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g. , some insoluble material present.

Table 35A 13C NMR Branching Analysis for Copolymers of Tables 33 and 34 Ex. Table En-Total Me Et Pr Bu Hex+ Am+& Bu+& try Me & eoc eoc eoc 103 33-1 34. 0 18. 7 7. 8 1. 1 1. 9 2.9 7. 2 6. 4 104 33-2 26.0 17.9 3.8 0.5 0.0 2.7 4.2 3.7 104 33-4 14.4 8.5 3.6 0.2 0.0 1.4 4.9 2.1 106 33-6 12.6 10.7 0.0 0.0 0.8 2.1 2.2 1.9 E 33-7 8.1 6.2 0.9 0.3 0.7 1.2 0.0 0.7 108 34-1 12.2 5.6 3.6 1. 1 0.4 0.7 1.1 1.8 109 34-2 15.5 11.6 1.0 0.7 0.0 0.9 1.6 2.2 111 34-4 10.5 7.9 1.0 0.1 0.0 0.7 0.4 1. 5 112 34-6 11.3 9.4 0.1 0.0 0.0 0.9 1.6 1.7 Table 35B Analysis of the Spacing (n) between Si and the Copolymer Backbone for Co- polymers of Tables 33 and 34 n=O n=1 n=2 n=3 n=4+ % % % % % 103 25. 62 20. 04 20. 97 7. 76 25.61 104 29.55 26.17 17.92 9.64 16.72 106 16.12 41.40 16.30 12.45 13.73 107 5.89 43.43 26.31 9.10 15.27 E 0 0 0 0 100 108 43.3 31.3 16.0 3.4 6.0 109 28.85 22.69 19.75 7.52 21.19 111 6. 41 45.75 25.79 8.01 14.04 112 26.0 42.8 15. 6 8.0 7.6

Examples 113-132 General Procedure for Ethylene Copolymerizations of Tables 36 and 37 in a nitrogen-purged drybox, a glass insert with a gas inlet was loaded with the specified amounts of B, B (C6F5) 3, LiB (C6F5) 42. 5Et2O, comonomer and p-xylene. The B (C6F5) 3 was the first ingredient added to all experiments and was added as a standard solution in THF. The THF was allowed to evaporate prior to the addition of the other reactants. The LiB (C6F5) 4 2. 5 Et20 was added as a standard solution in Et20 (0.0005 mmol per 0.2 mL Et2O), and B was added as a standard solution in a 10% solution of cyclopentene in Et20 (0.0005 mmol per 0.2 mL of solution). The order of addition was (1) B (C6F5) 3, (2) p-xylene, (3) comonomer, (4) LiB (C6F5) 4 2. 5Et20, and (5) B. The insert was greased and capped. The glass insert was then loaded in a pres- sure tube inside the drybox. The pressure tube was then sealed, brought out- side of the drybox, connected to the pressure reactor, placed under the de- sired ethylene pressure and shaken mechanically. After the stated reaction time, the ethylene pressure was released and the glass insert was removed from the pressure tube. The polymer was precipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution.

The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR spectra were run without Cr (acac) 3.

Table 36 Copolymerization of Ethylene (4.1 MPa) and H2C=CHSi(OR)xR'3-x(#5. 25 mmol, 10, 500 equiv) at 60°C with 0.0005 mmol B, 5.2 mg B(C6F5)3 (20 equiv) and 1 equiv LiB (CRFs) 4 for 18 h in p-Xylene (Total Volume VS + p-Xylene = 10 mL) Ex. Vinylsilane Yield VS M. W. Sol.,, Total g Incorp. Mea mol% a 113 H2C=CHSiMe3 0. 392 0. 12 ('H) Mw=68, 693 ; Mn=31, 646 S 17 5 (H) 114 H2C=CHSiMe3 0. 424 0. 21 ('H) Mw=59, 618 ; Mn=24, 237 S 17. 8 (l H) 115 VTEoS 2. 963 0. 99 ('H) MW=57, 530 ; Mn=9, 196 S 10. 4 ('H) 116 VTEoS 4. 415 1. 1 Mw=57 725 Mn=21, 745 P 8. 4 117 H2C=CHSiMe2 (OEt) 2. 247 0. 48 Mw=67, 037 ; Mn=25, 048 P 9. 5 118 H2C=CHSiMe2 (OEt) 3. 067 0. 43 Mu=43, 474 ; Mn=21, 043 S 13. 0 119 VTMOS 2. 269 1. 5 ('H) Mu=413503 ; Mn=16, 109 P 120 VTMOS 3. 900 1. 2 Mw=68, 791 ; Mn=23, 466 S 15. 0 121 H2C=CHSiMe (OMe) 2 2. 474 0. 95 Mw=57, 893 ; Mn=23, 722 S 8. 9 122 H2C=CHSiMe (OMe) 2 1. 888 1. 3 Mw=41, 486 ; Mn=20, 906 S 13. 5 Nd: Not determined. Data obtained from"C NMR unless specified otherwise. So). : Solu- bility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g. , some insoluble material present.

Table 37 Copolymerization of Ethylene (2. 8 MPa) and H2C=CHSi(OR)xR'3-x (#5.25 mmol, 10, 500 equiv) at 60°C with 0.0005 mmol B, 5.2 mg B (C^) a (20 equiv) <BR> <BR> <BR> and 1 equiv LiB(C6F5)4 for 18 h in p-Xvlene (Total Volume VS + p-Xylene = 10 mL) Ex. Vinylsilane Yield VS M. W. Sol. b Total g incorp. Mea mol% a 125 H2C=CHSiMe3 0. 921 0. 27 Mw=101, 579 ; Mn=30, 682 S 11. 4 126 H2C=CHSiMe3 0. 863 0. 36 Mu=531524 ; Mn=24, 595 S 15. 0 127 VTEOS 3. 709 2. 1 Mw=45, 175 ; Mn=19, 786 S 12. 8 128 VTEoS 4. 176 2. 2 MW=31, 498 ; Mn=13, 391 S 21. 1 129 H2C=CHSiMe2 (OEt) 3. 682 0. 99 Mw=37, 604 ; Mn=14, 739 S 17. 1 130 H2C=CHSiMe2 (OEt) 3. 482 1. 2 Mu=28, 759 ; Mn=9, 454 S 26. 3 131 VTMoS 2. 672 2. 0 MW=37, 318 ; Mn=16, 964 P 18. 6 132 VTMoS 3. 859 nd Mw=33, 483 ; Mn=14, 360 P nd 133 H2C=CHSiMe (OMe) 2 1. 173 1. 6 Mw=33, 119 ; Mn=15, 748 S 17. 1 134 H2C=CHSiMe (OMe) 2 2. 433 1. 8 Mu=32, 038 ; Mn=14, 919 S 15. 7

Nd: Not determined. ddata obtained from"C NMR unless specified otherwise. Soi. : Solu- bility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g. , some insoluble material present.

Table 38A 13C NMR Branching Analysis for Copolymers of Tables 36 and 37 Ex. Total Me Et Pr Bu Hex+ Am+ & Bu+ & Me & eoc eoc eoc 116 8. 4 6. 2 0. 2 0. 5 0. 8 0. 8 1.5 1.5 117 9.5 6.6 0.7 0.3 0.2 0.9 0.6 1.9 118 13.0 8. 7 1.6 0.8 0. 3 1.1 0.9 1.9 120 15.0 11.9 0.6 0.5 0.0 1.0 0.8 1.9 121 8.9 6.4 0.8 0.3 0.1 0.3 0.8 1.5 122 13.5 9.2 0.9 0.7 0.0 0.7 1.3 2.7 123 11.4 8.3 0.0 0.1 0.7 0.5 0.9 3.0 124 15.0 11.5 1.3 0.5 0.2 0.9 1.7 1.7 125 12.8 9.8 0.8 0. 6 0. 9 1.5 1.2 1.7 126 21.1 13.9 1.4 1.4 0.8 1.6 1.4 4.4 127 17.1 11.1 1.8 0.9 2.1 1.5 2.5 3.3 128 26.3 15.9 2.8 1.5 1.5 2.4 3.3 6.0 129 18.6 11.7 1.6 1.4 0.0 1.0 3.5 3.9 131 17.1 12.1 1.4 0.8 0. 0 0. 8 1.1 2.8 132 15.7 8.7 1.5 1. 6 0. 0 1. 0 2.0 3.9 Table 38B Analysis of the Spacing (n) between Si and the Copolymer Backbone for Co- polymers of Tables 36 and 37

Ex. n=0 n=1 n=2 n=3 n=4+ % % % % % 116 36. 73 16. 48 8.80 11.50 26.49 120 31.92 20.71 31.49 5.87 10.01 121-52-24-24 Trace'Trace' 122-54-23-23 Trace'Trace' 123 100 124 100 125 28.06 29.63 19.86 7.36 15.09 126 34.86 14.83 25.29 7.63 17.39 129 40.44 21.33 19.24 1.41 17.58 131-47-30-24 Some''Some" 132 #32 #29 #38 Somea Somea Present, but overlaps with other resonances.

Example 133 3-Vinyl-2, 4, 10-trioxa-3-silaadamantane, was synthesized by mixing 19.1 g (0.145 mol) of cis-flouroglucitol, 44.51 g (0.159 mol) of vinyl tris (2-methoxyethoxy) silane and 1.0 g sodium methoxide which were then heated until removal of calculated amount of 2- methoxyethanol. The resulting solid was purified by sublimation in vacuum.

Yield of 3-vinyl-2, 4, 10-trioxa-3-silaadamantane was 6.84 g (26%) as colorless crystals. 1H NMR (CD2C12) 1.80 (d, 3H, J=14 Hz), 2.49 (d, 3H, J-14Hz), 4.42 (br, s, 3H); 5.7-6. 2 (m, 3H). 13C NMR (CD2Cl2) 38.23 (s); 71.89 (s), 125.50 (s); 141.41 (s). 29Si NMR (C6D6) - 42. 50. The structure was confirmed by X-ray analysis.

Vials were loaded in a nitrogen filled glove box with 0.02 mmol of the transition metal catalyst, the catalyst [for EE 1.0 ml of 6.42% MMAO in heptane, for FF 50 eq. of B (C6F5) 3 (0.512 g) ], 0.6 g (0.00325 moles) of 3-vinyl-

2,4, 10-trioxa-3-silaadamantane, and 9 ml p.-xylene. The vials were placed in a shaker apparatus, heated to 60°C and pressured with ethylene to 2.8 MPa.

After 18 h the polymers produced were stirred with methanol, filtered, and washed 2 times with methanol on the filter and then one time with ether. The polymer samples were dried under vacuum (0.001 mm) over night. A polym- erization catalyzed by EE yielded 0.90 g of polymer with a vinylsilane incorpo- ration of 1.39 weight percent. The polymer has a melting point of 100. 8°C with a heat of fusion of 5.78 J/g, and a Mw of 78,900 A polymerization cata- lyzed by FF yielded 0.39 g of polymer with a vinylsilane incorporation of 0.41 weight percent. The polymer has a melting point of 116. 2°C with a heat of fusion of 115.6 J/g, and was insoluble in solvent.

Examples 134-149 and Comparative Examples J-V Ethylene Copolymerization with Vinylsilanes Using Supported Catalysts The polymerization of ethylene and vinylsilanes is described in Table 39, where conditions and ingredients are listed for each example, together with the results. Typical procedures for preparing the supported catalysts for three of the polymerization examples are given below.

Example 137 Catalyst Supported on B (Cw treated Silica support A 500 g sample of Grace/Davison Sylopol (g) 948 silica support (avail- able from Grace-Davison, W. R. Grace & Co. , Columbia, MD 21044, USA) was placed in an aluminum tray, covered with aluminum foil and placed in a vacuum oven with a dry nitrogen purge. The sample was heated for 18 h at 200°C. While still hot, it was quickly transferred to the inert nitrogen atmos- phere of a Vacuum Atmospheres drybox and the dried support was stored in a glass bottle. A 10 g portion of this dried support was placed in a screw cap jar and 100 mi toluene was added. B (C6F5) 3 (1 mmol, 0.512 g) was added and the slurry was placed on gentle shaker table overnight. The next day, the solid was filtered off and then dried under vacuum in the antechamber over- night. A sample (2.0 g) of the activated support was weighed into a vial. In a separate vial, a sample of B (0.1 mmol, 65mg) was dissolved in 25 mi toluene by placing it on the shaker for 30 min. All the catalyst appeared to be dis- solved in the toluene. The activated support was added to the solution and

the slurry was placed on the shaker overnight. The next day, the solid was allowed to settle out. The toluene had an orange color, indicating that not all the catalyst went onto the support. The residual toluene solution was de- canted and the remaining solid was washed with an aliquot of toluene. The resulting supported catalyst was dried under vacuum in the antechamber overnight.

A sample (100mgs, calculated 0.005 mmol Ni) of the supported cata- lyst was weighed into a tube. Cyclohexane (10 ml), vinyltriethoxysilane (2 ml) and triisobutylaluminum (0.250 ml, 5 eq) were added to the sample. The color of the catalyst changed from orange to a brown-green color. The tube was sealed and transferred outside the drybox. The polymerization was run for 16 h at 60°C and 3.45 MPa C2H4. The resulting polymer was collected by vac- uum filtration and washed thoroughly with methanol. It was dried in a vacuum oven under an N2 purge. Yield : 1.47 g Example 141 Catalyst supported on BF-treated Silica/alumina support Grace/Davison's silica/alumina support (500 gm of MS13-1. 1) was placed in an aluminum tray. It was covered with aluminum foil with several vent-holes. The sample was placed in a vacuum oven with a slow N2 purge. and heated for 18 h at 200°C. While the sample was still hot, it was quickly transferred to the inert atmosphere of a drybox and placed in a glass bottle.

In the drybox, 10 g samples of this support were weighed out. The 10 g por- tion was transferred to a screw cap jar and 100 ml of dried toluene was added. To the resulting suspension was added 1 mmol BF3 etherate (0. 127ml) and it was placed on a gentle shaker table overnight. The next day, the solid was filtered off. The sample was dried under vacuum at room tem- perature overnight. A 2.0 gram sample of this treated material was weighed out. B (1 mmol, 65 mg) was weighed into a screw cap jar and 25 ml of tolu- ene was added. After 30 min on a shaker, all the catalyst seemed to be dis- solved. The solution was added to the 2.0 g of treated support and placed on the shaker overnight. The next day, the solid was allowed to settle out. The toluene was colorless, indicating that all the catalyst had gone onto the sup- port. The toluene was removed by decantation and the sample was washed

with an aliquot of toluene. The resulting solid was dried under vacuum over- night and then stored in the drybox freezer until use.

For a polymerization, the supported catalyst (20 mg, 0.001 mmol) was weighed into a tube and cyclohexane (10 ml) was added, as were 2 ml VTEoS and 0.050 ml triisobutylaluminum via micropipet. When the triisobu- tylaluminum was added the catalyst appeared to become more blue-green in color. The tube was sealed and transferred outside drybox. The polymeriza- tion was run for 18 h at 60°C and 3.45 MPa C2H4. The tube was returned to the laboratory, opened, and the polymer was collected by vacuum filtration.

The polymer was washed thoroughly with methanol and dried in a vacuum oven. Yield : 1. 662 g. The samples were then analyzed by multiple means including MI and'H NMR Example 149 Catalyst supported on H S04.-treated Silica/alumina Suppo A 500 g sample of Grace/Davison silica/alumina MS13-1. 1 was dried in an aluminum tray in a vacuum oven with a nitrogen purge. The sample was heated for 18 h at 200°C and then transferred, still hot, to a drybox. A 10 g portion of this silica/alumina was transferred the to a screw cap jar and slur- ried in 100 mi of toluene. Concentrated sulfuric acid (1 mmol, 0.101 ml) was added to the slurry which was then shaken intermittently for 1 h and then al- lowed to stand overnight. The next day, the solid was collected by vacuum filtration and then dried under vacuum for 4 h. The solid was transferred to a jar and dried for 12 h in a tube furnace at 400°C under an N2 purge. The sample was sealed in a jar while under N2, then transferred to a drybox. The solid had a slightly gray color while previously the color was white. B (65 mg, 0.1 mmol) was dissolved in 25 ml of toluene, and placed on shaker for 30 min.

The sulfuric-acid-treated support (2.0 g) was added to the solution and the re- sulting slurry was placed on the shaker overnight. The next day, the solid was allowed to settle out. The toluene supernatant had a very slight purple color, indicating that almost all of the catalyst had gone onto the support. The su- pernatant was decanted and the solid was washed with an aliquot of toluene.

The solid product was dried under vacuum overnight. The solid was dark green in color.

To carry out a polymerization, the supported catalyst (100 mg, 0.005 mmol) was measured into a tube and 10 ml cyclohexane was added. VTEoS (2 ml) and triisobutylaluminum (0.250 ml) were added sequentially. The color became more blue-green in color and was very dark. The sample was sealed and transferred out of the drybox. The polymerization was run for 16 h at 60°C and 6.45 MPa ethylene. The resulting polymer was collected by vac- uum filtration and washed thoroughly with methanol. The sample was dried overnight in a vacuum oven. Yield : 9.35 g.

Table 39 Ex. Dried Support Catalyst Activator Shaker VTEoS ? Yield Productiv-VTEoS Support Treat- (5 eq) Condi- (g) ity Incorp. ment tion. (kgPE/gNi) (mole %) JSytopoiNoneEENone1No00 948 K Sylopol None EE AliBu3 1 No 0. 768 13 948 134 Sylopol None EE AliBu3 Yes 0 948 L Sylopol BF3 Et2O B AliBu3 1 No 0. 835 14 948 135 Sylopol BF3 Et20 AliBu3 Yes 0. 117 2 0. 30 948 M Sylopol B (C6F5) 3 EE AliBu3 2 No 1. 579 5. 4 948 136 Sylopol B (C6F5) 3 EE AliBu3 Yes 0. 690 2. 4 948 N Sylopol B (C6F5) 3 B iBu3 No 1. 95 6. 7 948 137 Sylopo ! B (C6F5) 3 B AliBu3 2 Yes 1. 47 5 948 138 Sylopol H2S04a EE AliBu3 2 Yes 1. 35 4. 6 NF 0. 0 948 139 Sylopol HZS04a'B AliBu3 2 Yes 2. 45 8. 4 NF 0. 0 948 O MS-13. 110 None EE None 1 No 0 0 P MS-13. 110 None EE AliBu3 1 No 1. 206 21 140 MS-13. 110 None B AliBu3 1 Yes 0. 256 4. 3 0. 30 141 MS-13. 110 BF3 Et20 B None 1 Yes 1. 662 28 142 MS-13. 110 BPh3 B AliBu3 2 No 3. 14 11-- 143 MS-13. 110 BPh3 B Al Bu3 2 Yes 0. 575 2 0. 68 Q MS-13. 110 B (C6F5) 3 EE AliBu3 2 No 3. 76 13 144 MS-13. 110 B (C6F5) 3 EE AliBu3 2 Yes 0. 690 2. 4 0. 5 R MS-13. 110 B (C6F5) 3 B AliBu3 2 No 4. 65 16 145 MS-13. 110 B (C6Fs) 3 B AliBu3 2 Yes 1. 53 5 0. 08 S MS-13. 110 AI (iBu) 3 EE AliBu3 2 No 3. 01 10 146 MS-13. 110 AI (iBu) 3 EE AliBu3 2 Yes 0. 280 1 T MS-13. 110 AI iBu 3 B AliBu3 2 No 3. 25 11 147 MS-13. 110 Al (iBu) 3 B AliBu3 2 Yes 0. 505 2 U MS-13. 110 H2SO4a EE AliBu3 2 No 3. 38 12 N F 148 MS-13. 110 H2SO4a EE AliBu3 2 Yes 3. 10 11 NF 0. 1 V MS-13. 110 H2SO4a) B AliBu3 2 No 5. 0 17 0. 06 149 MS-13. 110 H2SO4a B AliBu3 2 Yes 9. 35 32 NF 1. 0 Description of General Procedure : Dry the support indicated in Dried Support column at 200 °C. Treat 10 g of the Dried Support in toluene with the Lewis acid or compound indicated in the Support Treatment column and then redry the support under vacuum and nitrogen. 5 Support 0. 1 mmol of the catalyst indicated in Catalyst column on 2 g of the treated support. The Yield, productivity, MI and percent VTEoS incorporated are indicated in subsequent columns. Polymerization Conditions 1. 60°C and 3. 5 MPa ethylene with 0. 001 mmol of the catalyst and the activator indicated in column 6, with or without 2 mL of VTEoS comonomer as indicated in col- umn 7. 10 2. 60°C and 3. 5 MPa ethylene with 0. 005 mmol of the catalyst and the activator indicated in column 6, with or without 2 mL of VTEoS comonomer as indicated in column 7. NF signifies No Flow in the melt indexer.

Examples 150-151 and Comparative Examples W-X SMAO-Supported Catalysts for ethylene copolymerization with Vinylsilanes The catalysts used in this series of experiments were A and EE. The support employed was SMAO (XPO-2409) which is a silica support which has been pretreated with methylaluminoxane by a Albemarle Corp. The polymer- zations were carried out in a shaker tube run at 60°C and 3.5 MPa ethylene with 0.001 mmol of the catalyst and the activator indicated in column 6, with or without 2 mL of VTEoS comonomer as indicated in column. The boron com- pounds, B (C6F5) 3 and LiB (C6F5) 4 were added at a level of 5 equivalents based upon Ni. The results are included in Table 40. The Mls of the vinylsilane- containing copolymers are the same as those observed without comonomer.

Vinylsilane comonomer was incorporated to an appreciable level (1-2 mole%), and it did not crosslink despite the fact that SMAO has appreciable Lewis acidity. The prealkylated catalyst (EE) gave productivities similar to those of the non-alkylated catalyst. Thus, there would be no need to utilize this more expensive system. The results with and without vinyl silane mirror those of A.

Table 40 Ex. Catalyst Equiv Equiv VTEoS Yield Product. M Silane No. Borane Borate (1 m L) (g) kgPE/gN i (mole%) W A 5 5 No 6. 60 11. 3. 2 150 A 5 5 Yes 6.50 11.1 .4 1.5 X EE 5 5 No 7. 45 12. 7. 2 151 EE 5 5 Yes 5.62 9.57 1.9 2.2 General Information for Examples 152-184: B (C6F5) 3, [HNMe2Ph] [B (C6F5) 4] and Li [B (C6F5) 4] (Et2O) xwere purchased from Boulder Scientific. B (C6H5) 3 was purchased from Aldrich. A ! Me (BHT) 2 and AIEt (BHT) 2 were prepared by literature methods; (a) Shreve, A. P.; Mul- haupt, R.; Fultz, W.; Calabrese, J.; Robbins, W.; Ittel, S. D. Organometallics 1988,7, 409. (b) Healy, M. D.; Wierda, D. A.; Barron, A. R. Organometallics 1988, 7,2543. B ( (3, 5-CF3) 2-C6H3) 3 was prepared by literature method; Brookhart, M.; Grant, B.; Volpe, A. F. , Jr. Organometallics 1992, 11, 3920.

[AlMe2 (Et2O) 2] [MeB (C6F5) 3] was prepared by literature methods; (a) Klosin, J.; Roof, G. R.; Chen, E. Y. -X. ; Abboud, K. A. Organometallics 2000, 19, 4684. <BR> <BR> <P>(b) Klosin, J. PCT Int. Appl. WO 0011006 (Dow Chemical Co. ). [Ph3C] [B ( (3, 5-

CF3) 2-C6H3) 4] was prepared by literature method; Bahr, S. R.; Boudjouk, P.; J.

Org. Chem : 1992,57, 5545.

Examples 152-159 Ethylene Copolymerization with VTEoS with 1 to 5 Equivalents of Activator per Nickel General Polymerization Procedure In a drybox, a glass insert was loaded with a diethyl ether solution of cocatalyst. The diethyl ether was allowed to evaporate. A solution of 7.8 g of p-xylene, 0.9 g VTEoS and 14.3 mg of Li [B (C6F5) 4] was added. A solution of B in diethyl ether was added and the insert was then capped and sealed in a tube. Outside of the drybox, the tube was placed under ethylene (4. 1 MPa) and was shaken mechanically at 60°C for about 16 h. The resulting reaction mixture was mixed with methanol (with a small amount of triethylamine, ap- proximately 0.1 vol%), filtered, repeatedly washed with methanol and the solid polymer dried in vacuo. Results are shown in Table 41, where"Mole%"refers to the mole percent incorporation of VTEoS monomer into the polymers. The Mole% was determined by 1H NMR spectroscopy on about 10 mg sample of isolated polymer diluted in 0.5 mi TCE-d2 at 120°C.

The solutions of cocatalysts were prepared from 0.04 mmol of cocata- lyst in 8.47 g of diethyl ether. An aliquot of 0.30 mL was used for 0.001 mmol of cocatalyst. Alternatively, a solution of catalyst prepared from 0.1 mmol of catalyst in 4.24 g of diethyl ether was used for 0.005 mmol of catalyst from a 0.30 mL aliquot of stock solution.

The solution of catalyst B was prepared from 26 mg B (0.04 mmol) and 11.3 g of diethyl ether. The solution was stored in the drybox freezer at- 30°C. An aliquot of 0.4 mL catalyst B stock solution is used for 0.001 mmol catalyst and an aliquot of 0.2 mL catalyst B stock solution is used for 0.0005 mmol catalyst.

Table 41 x Catalyst Cocatalyst (mmol) Yield (g) Mole% M. W. (mmol) VTEoS 52 B (0. 001) B (C6F5) 3 (0. 001) 3. 207 1. 03 MW=51, 859 Mn=27, 548 53 B (0. 001) AlMe (BHT) 2 (0. 001) 5. 347 2. 0 Mw=48, 725 Mn=23, 688 54 B (0. 001) B (C6H5) 3 (0. 001) 2. 369 1. 78 Mw=46, 829 Mn=26, 000 55 B (0. 001) B ( 5-CF3) 2-C6H3) 3 (0 001) 4. 569 2. 1 MW=45X299 Mn=21, 041 56 B (0. 001) AlEt (BHT) 2 (0. 001) 3. 33 1. 32 MW=56SO87 Mn=23, 834 57 B [AlMe2 (Et2O) 2] [MeB (C6F5) 3] (0. 001) 5. 086 2. 03 Mw=46, 503 (0. 0005) Mn=20, 888 (0. 0005) 58 B (0. 001) [HNMe2Ph] [B (C6F5) 4] (0. 005) 5. 409 3. 94 MW=60s227 Mn=18, 306 59 B (0. 001) [Ph3C] [B (CeF5) 4] (0. 005) 5. 57 1. 29 Mw=87, 979 Mn=21, 639

Conditions: LiB (C6F5) 4 (0. 001 mmol), 9mL p-xylene, 1 mL VTEoS, 60 °C, 4.1 MPa, 16h.

Examples 160-184Ethylene Copolymerization with VTEoS Using Supported Catalysts A 500 g sample of Grace/Davison Sylopol0 948 silica support (avail- able from Grace-Davison, W. R. Grace & Co., Columbia, MD 21044, USA) was placed in an aluminum tray, covered with aluminum foil and placed in a vacuum oven with a dry nitrogen purge. The sample was heated for 18 h at 200°C. While still hot, it was quickly transferred to the inert nitrogen atmos- phere of a Vacuum Atmospheres drybox and the dried support was stored in a glass bottle.

Example 160 Synthesis of Catalyst A 0.5 g sample of dried Sylopol 948 was added to a vial with 6.9 g of toluene, 13 mg of B (C6F5) 3 and 2 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 2 hours. The slurry was filtered and rinsed 3 times with toluene (10 mL) and dried under vacuum for 1 h. The

isolated solid was added to a vial with 6.9 g of toluene and a sample of B (0.025 mmol, 16 mg). The sample vial was capped and mechanically shaken for 2 h. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and dried under vacuum for 1 h.

Example 161 Synthesis of Catalyst A 0.5 g sample of dried Sylopol 948 was added to a vial with 6.9 g of toluene, 26 mg of B (C6F5) 3 and 2 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 1 h and was allowed to stand overnight and shaken again for 1 h. The slurry was filtered and rinsed 3 times with tolu- ene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min. The isolated solid was added to a vial with 6.9 g of toluene and a sample of B (0.025 mmol, 16 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min.

Example 162 Synthesis of Catalyst A 0.5 g sample of dried Sylopol 948 was added to a vial with 6.9 g of toluene and 50 mg of PMAO-IP. The sample vial was capped and mechani- cally shaken for 2 h. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min. The isolated solid was added to a vial with 6.9 g of tolu- ene with 26 mg of B (C6F5) 3 and 2 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 2 h. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min. The isolated solid was added to a vial with 6.9 g of toluene and a sample of B (0.025 mmol, 16 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min.

Example 163 Synthesis of Catalvst A 0.25 g sample of dried Sylopol 948 was added to a vial with 6.9 g of toluene, 0.025 mmol of AlMe3 (2.0 M in toluene and added to 0.5 mL of Et20)

and 13 mg of B (C6F5) 3. The sample vial was capped and mechanically shaken for 2 h. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min. The isolated solid was added to a vial with 6.9 g of toluene and a sample of B (0.0123 mmol, 8 mg). The sample vial was capped and me- chanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min.

Example 164 Synthesis of Catalyst A 1.00 g sample of dried Sylopol 948 was added to a vial with 6.9 g of toluene, 51 mg of B (C6F5) 3 and 4 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 2 h. The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min. The isolated solid was added to a vial with 6.9 g of toluene and a sample of B (0.050 mmol, 32 mg) in 2 g of toluene. The sample vial was capped and mechanically shaken for 30 min.

The slurry was filtered and rinsed 3 times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min.

Example 165 Synthesis of Catalyst A 0.5 g sample of SMAO (12 wt. % Al) was added to a vial with 6.9 g of toluene and a sample of A (0.025 mmol, 16 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and dried under vacuum for 1 h.

Example 166 Synthesis of Catalyst A 0.5 g sample of SMAO (12 wt. % Al) was added to a vial with 6.9 g of toluene, 20 mg of [HNMe2Ph] [B (C6F5) 4] and a sample of A (0.025 mmol, 16 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and dried under vacuum for 1 h.

Example 167 Synthesis of CatalYst A 0.25 g sample of SMAO (12 wt. % Al) was added to a vial with 6.9 g of toluene and a sample of B (0.0123 mmol, 8 mg). The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3

times with toluene (10 mL each) and rinsed 3 times with pentane (10 mL each) and dried under vacuum for 30 min.

Examples 168-184 General Polymerization Procedure In a drybox, a glass insert was loaded with a Ni catalyst supported on a silica-based support. A solution of 7.4 g cyclohexane and 0.45 g of VTEoS was added. A solid portion of catalyst (Ex. 173-174) or a solution of co- catalyst (Ex. 176-180) was added and the insert was capped and sealed in a tube. Outside of the drybox, the tube was placed under ethylene and was shaken mechanically at the temperature indicated in tables 2-4 for about 16 h.

The resulting reaction mixture was mixed with methanol (with a small amount of triethylamine, approximately 0.1 vol%), filtered, repeatedly washed with methanol and the solid polymer dried in vacuo.

A solution of AlMe (BHT) 2 was prepared from 0.02 mmol in 7.38 g of cyclohexane. An aliquot of 0.30 mL was used for 0.0005 mmol or 0.60 mL for 0.001 mmol. Alternatively, a solution of AIMe (BHT) 2 was prepared from 0.1 mmol in 2.34 g of cyclohexane. An aliquot of 0.15 mL was used for 0.005 mmol or 0.30 mL for 0.010 mmol or 0.60 mL for 0.20 mmol. The amount of cyclohexane added with the AlMe (BHT) 2 catalyst was subtracted from the amount added as the polymerization solvent so that the total solvent volume was 10 mL.

"Mole%"in Tables 42-44 refers to the mole percent incorporation of that monomer into the polymers. The Mole% was determined by 1H NMR spectroscopy on about 10 mg sample of isolated polymer diluted in 0.5 mi TCE-d2 at 120°C.

Table 42 Ex Example for mmol Yield (g) Mole% VTEoS M. W. Catalyst (wt. Nia mg) 168 160 (50) 0. 0025 5. 474 0. 74 MW=83o526 Mn=11, 857 169 161 (50) 0. 0025 5. 414 0. 16 Mw=148, 925 Mn=31, 186 170 162 (50) 0. 0025 4. 684 0. 11 MW=108, 459 Mn=31, 698 171 163 (50) 0. 001 1. 87 0. 87 MW=61, 345 Mn=22, 428 172 162 (50) 0. 001 2. 187 0. 09 | Mw=125X933 Mn=34, 798

Conditions: 9.5mL cyclohexane, 0. 5mLV TEoS, 60 °C, 4.1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Table 43 K Ex. # for mmol Temp Cocatalyst (mmol) Yield Mole% M. W. Catalyst Nia (OC) (g) VTEoS (wt. mg) 3 164 (4) 0. 0002 RT B (C6F5) 3 (0. 025) 0. 896 0. 09 Mw=305, 70 0 Mn=74, 351 4 164 (4) 0. 0002 RT AlMe (BHT) 2 2. 279 <0. 1 Mw=301, 66 (0. 025) 3 Mon=84, 544 5 164 (4) 0. 0002 RT PMAO-IP (0. 17) 7. 306 0. 2 Mw=485, 86 0 Mn=92, 239 '6 164 (10) 0. 0005 60 AlMe (BHT) 2 0. 098 (0. 0005) '7 164 (10) 0. 0005 60 AlMe (BHT) 2 0. 541 (0. 001) '8 164 (10) 0. 0005 60 AlMe (BHT) 2 0. 83-MW=161, 02 (0. 005) 8 Mn=30, 360 '9 164 (10)--0. 0005 60 AlMe (BHT) 2 (0. 01) 1. 914- , 0 164 (10) 0. 0005 60 AIMe (BHT) 2 (0. 02) 2. 792 0. 46 MW=145, 85 3 Mon=28, 369 Conditions: 9.5mL cyclohexane, 0.5mL VTEoS, 4.1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Table 44 Ex Ex. # for mmol Temp Yield (g) Mole% M. W. Catalyst (wt. Nia (°C) VTEoS mg) 181 165 (50) 0. 0025 60 4. 501 0. 12 MW=237, 796 Mn=35, 525 182 166 (50) 0. 0025 60 6. 292 2. 07 Mw=54, 788 Mn=12, 997 183 165 (20) 0. 001 75 1. 368 0. 17 MW=1767977 Mn=29, 688 184 167 (20) 0. 001 75 3. 703 0. 29

Conditions: 9.5mL cyclohexane, 0.5mL VTEoS, 4.1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Example 185 Supported Iron Catalyst Preparation In a drybox, 14 mg of 2, 6-bis [1- (2, 4,6- trimethylphenylimino) ethyl] pyridine iron dichloride was dissolved in 10 ml of toluene in a scintillation vial and 1 g of dehydrated silica (Grace Davidson grade 948) was added. The deep blue mixture was shaken for 30 min. The mixture was filtered through a coarse sintered glass frit and the solids were dried overnight in vacuum at RT. About 1 g of light blue solid was obtained.

Example 186 Polymerization with Supported Iron Catalyst In a dry box, 21.3 mg of the catalyst prepared in Example 185 was mixed with 5 ml of anhydrous toluene and transferred to a reactor injector tube. Also in the drybox, 1 ml of a 1 M solution of triisobutylaluminum (Aldrich) was mixed with 4 ml of toluene and transferred to another reactor injector tube. The autoclave reactor (500 ml Autoclave Engineers Zipperclave0 re- actor, equipped with a stirrer driven by an electric motor) was charge with 150 ml of anhydrous cyclohexane (Aldrich) and heated to 50°C. VTMoS (25 ml) was charged to a pump attached to the reactor. The pumping rate was set to 12.5 mi/h (0.2 ml/min). First, the catalyst was injected into the cyclo- hexane solvent, then the ethylene feed was started to pressurize the reactor to 1.03 MPa. The catalyst was injected into the pressurized reactor, followed by immediate starting of the comonomer pumping. The reaction was allowed

to proceed for two h. At the end of the run, the dried polymer yield was 0.3 g, and the silane content by 1H-NMR was 0.019% mol (0.1 wt%).

Example 187 Preparation of a Supported Catalyst HH, prepared by the method described in U. S. Patent Application 10/108, 938, filed March 27,2002, which is hereby included by reference, was supported on silica as follows. Silica (8 g) was mixed with 40 mL of dry tolu- ene and 12 mL of a 2 M Me3AI hexane solution were added. During the pe- riod of two hours, the reaction mixture was shaken several times. The silica was finally washed three times with toluene and once with pentane. The silica was dried in vacuum at 25°C. HH was stirred for 15 minutes in 10 mL CH2CI2, and the silica (300 mg) was added. After 1 h the CH2CI2 phase was removed under vacuum and the brown solid was washed once with CH2CI2.

Example 188 Polymerization with Supported Nickel Catalvst In a dry box, 54.2 mg of the supported catalyst prepared in Example 187 was mixed with 6 ml of VTMoS and was transferred to a reactor injector tube. Also in the drybox, 1.3 mi of 1 M solution of ethyl aluminum sesquichlo- ride (Aldrich) was transferred to another reactor injector tube. The autoclave reactor described in Example 186 was charged with 250 mi anhydrous cyclo- hexane (Aldrich). First, the catalyst was injected to the cyclohexane sol- vent, then the reactor was heated to 60°C, and then the ethylene feed was started to pressurize the reactor to 4.14 MPa. The catalyst and comonomer were injected into the pressurized reactor. The reaction was allowed to pro- ceed for one h. At the end of the run, the dried polymer yield was 6.7 g, and the silane content by'H-NMR was 0.0151 mol % (0.08 wt%).

Example 189 Polymerization with Supported Nickel Catalyst With Hydrogen.

In a dry box, 56.1 mg of the supported catalyst prepared in Example 187 was mixed with 3 ml of VTMoS which was transferred to a reactor injector tube. Also in the drybox, 1.3 ml of a 1 M solution of ethyl aluminum ses- quichloride (Aldrich) was transferred to another reactor injector tube. The autoclave reactor described in Example 186 was charged with 250 ml anhy-

drous cyclohexane (Aldrich). The catalyst was transferred to the reactor and the solvent was saturated with 69 kPa of hydrogen. The reactor was then heated to 60°C. The ethylene feed was started to pressurize the reactor to 4.14 MPa. The catalyst and comonomer were injected into the pressurized reactor. The reaction was allowed to proceed for one h. At the end of the run, the dried polymer yield was 5.1 g, and the silane content by 1 H-NMR was 0.0192% mol (0. 1 wt%).

Example 190 Polymerization with Supported Nickel Catalyst In a dry box, 50.2 mg of the supported catalyst prepared in Example 187 was mixed with 5 ml of anhydrous toluene. Also in the drybox, 2.5 ml of a 1 M solution of ethyl aluminum sesquichloride (Aldrich) was transferred to an- other reactor injector tube. The autoclave reactor described in Example 186 was charge with 250 ml anhydrous cyclohexane (Aldrich). The reactor was heated to 60°C, then the ethylene feed was started to pressurize the reactor to 4.14 MPa. The catalyst was injected to the pressurized reactor. VTMoS (25 ml) was charged to a pump attached to the reactor. The pumping rate was set to 25 much (0.4 ml/min). Immediately after the ethylene feed was started to the reactor, comonomer pumping was started. The reaction was allowed to proceed for one h. At the end of the run, the dried polymer yield was 25.1 g, and the silane content by 1 H-NMR was 0.126 mol % (0.66 wt%).

Example 191 Polymerization with Supported Nickel Catalyst with Hydrogen In a dry box, 54.4 mg of the supported catalyst prepared in Example 187 was mixed with 5 ml of anhydrous toluene. Also in the drybox, 2. 5 cc of a 1 M solution of ethyl aluminum sesquichloride (Aldrich) was transferred to an- other reactor injector tube. The autoclave reactor described in Example 186 was charge with 150 ml anhydrous cyclohexane (Aldrich). The reactor was heated to 60°C, then the ethylene feed was started to pressurize the reactor to 4.14 MPa. The catalyst was injected into the pressurized reactor. VTMoS (25 ml) was charged to a pump attached to the reactor. The pumping rate was set to 25 ml/h (0.4 ml/min). Immediately after the ethylene feed was started to the reactor, the comonomer pumping was started. The reaction was allowed to proceed for one h. At the end of the run, the dried polymer

yield was 17.2 g, and the silane content by 1H-NMR was 0.1776 mol % (0.93 wt%). The 2.26 Kg Melt Index was 0.08.

Example 192 Polymerization with Supported Nickel Catalyst with Hydrogen In a dry box, 25.0 mg of the supported catalyst prepared in Example 187 was mixed with 5 ml of anhydrous toluene. Also in the drybox, 1.3 ml of a 1 M solution of ethyl aluminum sesquichloride (Aldrich) was transferred to an- other reactor injector tube. The autoclave reactor described in Example 186 was charged with 250 ml anhydrous cyclohexane (Aldrich). The catalyst was injected in the reactor and then the solvent was saturated with 620 kPa of hydrogen. Then, the reactor was heated to 60°C, and then the ethylene feed was started to pressurize the reactor to 4.14 MPa. The catalyst was injected into the pressurized reactor. VTMoS (25 ml) was charged to a pump attached to the reactor. The pumping rate was set to 25 much (0.4 ml/min). Immedi- ately after the ethylene feed was started to the reactor, the comonomer pumping was started. The reaction was allowed to proceed for one h. At the end of the run, the dried polymer yield was 4.8 g, and the silane content by 1 H-NMR was 0.0313% mol % (0.165 wt%). The 2.16Kg melt index was 0.5.

Example 193 Polymerization with Supported Nickel Catalyst with Hydrogen In a dry box, 25.3 mg of the supported catalyst prepared in Example 187 was mixed with 5 ml of anhydrous toluene. Also in the drybox, 1.3 cc of a 1 M solution of ethyl aluminum sesquichloride (Aldrich) was transferred to an- other reactor injector tube. The autoclave reactor described in Example 186 was charged with 250 mi anhydrous cyclohexane (Aldrich). VTMoS (62. 5moi) was charged to a pump attached to the reactor. The pumping rate was set to 62.5 mllh (1. 04 ml/min). First, the catalyst was injected into the reactor, then the reactor contents were saturated with 620 kPa of hydrogen. The re- actor was heated to 60°C, then the ethylene feed was started to pressurize the reactor to 4.14 MPa. The catalyst was injected into the pressurized reac- tor. Immediately after the ethylene feed was started to the reactor, comono- mer pumping was started. The reaction was allowed to proceed for one h. At the end of the run, the dried polymer yield was 1.6 g, and the silane content by 1H-NMR was 0.1018 mol % (0.54 wt%).

Example 194 Preparation of a Crosslinked Polvstvrene Supported Cataly Crosslinked polystyrene containing-C6H4CH2NMe2H+ [B (C6F5) 4]-func- tionality was prepared from commercial Merrifield resin (Aldrich, 100-200 mesh, 1 % crosslinked, 1.09 milliequiv. of Cl per gram of resin) using a pub- lished procedure (Frechet, J. M., et. a/., Science, 1998, 280, p. 270-274 and US patent 6,228, 795 B1.). Based on the weight change of the resin during the preparation, the degree of functionalization was estimated as 0.63 millie- quiv. of borate per gram of resin. A solution of B (12.4 mg, 19. 1 mole) in 1.0 mL of toluene was added to 0.307 g of the polystyrene supported borate co- catalyst (10 mole equiv. borate per Ni) and mixed for 90 minutes. Cyclohex- ane (2 mL) was added and mixed briefly, and then the supported catalyst slurry was allowed to settle and the solvent was decanted. The washing and decanting with cyclohexane were repeated two more times, and then the blue/black supported catalyst was dried in vacuo at room temperature for 1 h and used immediately for polymerization (Example 341).

Examples 195-200 Polymerization with Chain Transfer Agent In a dry box, about 14 mg of the catalyst prepared in Example 194 was mixed with 5 ml of VTMoS and transferred to a reactor injector tube. Also in the drybox, about 200 mg of triphenylborane was mixed with 5 mi of anhy- drous toluene and transferred to another reactor injector tube. The autoclave \ reactor described in Example 186 was charged with 250 ml of anhydrous cy- clohexane (Aldrich) and mixed with the designated amount of triisobutylalumi- num (Aldrich 1 M in hexanes). The triphenylborane solution was then added to the reactor. The reactor was heated to 70°C and pressurized to 2.41 MPa with ethylene. The catalyst with the VTMoS was injected to the cyclohexane solvent, and then the reactor pressure was adjusted to 2. 76 MPa. The reac- tion was allowed to proceed for one h. At the end of the run, the polymer col- lected and dried in the vacuum oven. The molecular weights were measured by GPC (PE standard). The results are shown in Table 45.

Table 45 Ex. (i-Bu) 3Al Catalyst VTMoS TBP Polymer VTMoS Mn Mw ml (mg) (mi) (mg) mole % 195 1. 00 14. 4 2. 5 202. 7 15.1 0.29 5579 14548 196 0.50 15.2 2.5 209.4 24.7 0.124 6806 15474 197 0.25 14.1 2.5 207.0 1. 4 0.18 6623 16154 198 0.35 16.2 2.5 203.1 0.3 0.60 10544 28290 199 0.75 15.9 2.5 203. 6 6.7 NA 5836 15818 200 0.65 13.5 2. 5 202.5 6. 3 NA 6293 15699

Examples 201-235 General Procedure for EthyleneNTEoS Copolymerizations of Table 46 In a nitrogen-purged drybox, a glass insert with a gas inlet was loaded with the specified amounts of B, B (C6F5) 3, LiB (C6F5) 42. 5Et2O, VTEoS and p- xylene. The B (C6F5) 3 was the first ingredient added to all experiments and was added as a standard solution in THF. The THF was allowed to evaporate prior to the addition of the other reactants. The LiB (C6F5) 42. 5 Et2O was added as a standard solution in Et20 (0.0005 mmol per 0.2 mL Et20), and B was also added as a standard solution in Et20 (0.0002 mmol per 0.2 mL Et2L) except in the case of entries 11-15 of Table 10S, where B was added as a standard solution in a 5% solution of cyclopentene in Et2O (0.0002 mmol per 0.2 mL of solution). The order of addition for entries 201,206, 211-216,221, 226 and 231 of Table 46 was (1) B (C6F5) 3, (2) LiB (C6F5) 42. 5Et2O, (3) B, (4) p- xylene and (5) VTEoS. For the remaining entries, the order of addition was (1) B (C6F5) 3, (2) p-xylene, (3) VTEoS, (4) LiB (C6F5) 42. 5Et20, and (5) B. The insert was greased and capped. The glass insert was then loaded in a pres- sure tube inside the drybox. The pressure tube was then sealed, brought out- side of the drybox, connected to the pressure reactor, placed under the de- sired ethylene pressure and shaken mechanically. After the stated reaction time, the ethylene pressure was released and the glass insert was removed from the pressure tube. The polymer was precipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution.

The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR

spectra were run without Cr (acac) 3. Experimental details and results are given in Tables 46-48.

Table 46 Copolymerization of Ethylene and VTEoS at 4.1 MPa E with 0.0002 mmol of B: Variation of Temperature, B (C6F5) 3 Concentration, and VTEoS Concentration (10 mL Total Volume of VTEoS + p-Xylene, 0.0005 mmol LiB (C6F5) 42. 5 Et2O, 18 h) Ex. B (C6Fs) 3 VTEoS Temp. Yield VTEoS M. W. Sol. a Total mg mL °C g incorp. Me Mol% 201 1. 3 0. 7 30 0. 02 nd nd nd nd 202 5. 2 0. 7 30 0. 02 nd nd nd nd 203 5. 2 1. 4 30 0. 01 nd nd nd nd 204 10. 4 0. 7 30 0. 06 nd nd nd nd 205 10. 4 1. 4 30 0 nd nd nd nd 206 1. 3 0. 7 50 0. 87 0. 8 Mp=72, 618 ; S 12. 4 ('H) MW=69, 604 ; ('H) 0. 7 Mn=9, 230 ; 4. 1 ('3C) PDI=7. 54 (13c) 207 5. 2 0. 7 50 0. 66 0. 7 Mp=69, 942 ; S 14. 0 (H) Mu 99, 583 ; (1 H) Mn=8, 243 ; PDI=12. 08 208 5. 2 1. 4 50 1. 23 1. 2 Mp=60, 663 ; S 7. 3 ('H) (1H) Mw=84, 791 ; 4. 3 1. 0 Mn=27, 358 ; (13C) (13c) PDI=3. 10 209 10. 4 0. 7 50 0. 25 0. 7 Mp=43, 278 ; P 17. 9 (H) M=71, 222 ; (1 H) Mn=19, 120 ; PDI=3. 73 210 10. 4 1. 4 50 0. 39 1. 0 Mp=45, 358 ; P 6. 9 (1 H) Mw=63, 335 ; (1 H) Mn=21, 154 ; PDI=2. 99 211 2. 6 0. 7 60 3. 14 0. 7 Mp=53, 031 ; S 11. 9 (1 H) Mw=79, 978 ; (1 H) Mn=23, 416 ; PDI=3. 42 212 1. 3 0. 7 60 2. 98 0. 8 Mp=51, 330 ; S 10. 8 ('H) Mw=69, 477 ; ('H) Mn=21, 102 ; PDI=3. 29 213 2. 6 1. 4 60 3. 28 1. 6 Mp=33, 643 ; P 11. 8 ('H) Mw=47, 289 ; ('H) Mn=16, 204 ; PDI=2. 92 214 1. 3 1. 4 60 2. 75 1. 6 Mp=33, 243 ; P 10. 8 (1 H) Mw=49, 593 ; (1 H) Mn=16, 573 ; PDI=2. 99 Table 46 (cont'd) Ex. B (C6F5) 3 VTEoS Temp. Yield VTEoS M. W. Sol. Total mg mL °C g Incorp. Me Mol% 215 10. 4 0. 7 60 5. 19 0. 7 Mp=50, 329 ; S 13. 0 (H) Mw=74, 455 ; ('H) Mn=22, 313 ; PDI=3. 34 216 1. 3 0. 7 70 2. 21 0. 9 Mp=41, 800 ; S 15. 8 ('H) MW=57, 876 ; ('H) 0. 5 Mn=19, 868 ; 14. 1 (13C) PDI=2. 91 (13C 217 5. 2 0. 7 70 2. 35 1. 8 Mp=40, 910 ; S 30. 3 ('H) MW=71, 041 ; ('H) Mn=21, 973 ; PDI=3. 23 218 5. 2 1. 4 70 0. 69 1. 8 Mp=26, 364 ; S 14. 7 (1H) MW=30, 199 ; (1H) Mn=13, 279 ; PDI=2. 27 219 10. 4 0. 7 70 2. 44 0. 7 Mp=44, 204 ; S 14. 2 ('H) Mw=77, 166 ; (1 H) Mur=21, 908 PDI=3. 52 P 124 220 10. 4 1. 4 70 2. 46 1. 3 Mp=27, 289 ; P 12. 4 ('H) M, =38, 273 ; (1 H) Mn=13, 875 ; PDI=2. 76 221 1. 3 0. 7 70 0. 012 nd nd nd nd S 20. 9 222 5. 2 0. 7 70 3. 80 1. 1 Mp=39, 923 ; S 20. 9 (1 H) MW=43I258 ; ('H) 1. 0 Mn=19, 549 ; 15. 2 (13C) PD ! =2. 21 (C) 223 5. 2 1. 4 70 0. 023 nd nd nd nd 224 10. 4 0. 7 70 3. 44 0. 8 Mp=38, 792 ; S 18. 1 (1 H) MW=67X46O ; ('H) Mn=21, 552 ; PDI=3. 13 P 24. 4 225 10. 4 1. 4 70 0. 74 2. 4 Mp=18, 512 ; 24. 4 (1H) MW=20, 211 ; (lH) Mn=9, 317 ; PDI=2. 17 226 1. 3 0. 7 90 2. 22 1. 6 Mp=25, 692 ; S 29. 6 ('H) Mw=27, 412 ; (1 H) 1. 2 Mn=10, 944 ; 26. 1 (13C) PDI=2. 50 (13C 227 5. 2 0. 7 90 3. 75 1. 1 Mp=23, 758 ; S 32. 1 (H) M, mu=25, 690 ; (1 H) 1. 2 Mn=11, 350 ; 32. 1 (13C) PDI=2. 26 Table 46 (cont'd) Ex. B (C6F5) 3 VTEoS Temp. Yield VTEoS M. W. Sol. Total mg mL °C g incorp. Me Mol% 228 5. 2 1. 4 90 3. 02 1. 3 Mp=22, 878 ; S 314. 5 S 34. 5 MW=24X258 ; ('H) 1. 3 Mn=11, 233 ; 28. 0 (13C) PDI=2. 16 (13c) 229 10. 4 0. 7 90 4. 06 1. 6 Mp=22, 075 ; S 44. 5 ('H) MW=23, 412 ; (1H) 1. 2 Mn=10, 223 ; 35. 0 (13C) PDI=2. 29 (C) 230 10. 4 1. 4 90 3. 48 1. 4 Mp=22, 169 ; S 37. 1 MW=23X992 ; (H) 1. 3 Mn 10, 050 ; 34. 5 - (13C) PDI=2. 39 (13C 231 1. 3 0. 7 110 0. 65 1. 2 Mp=13, 939 ; S 46. 9 ('H) MW=22, 634 ; ('H) 1. 3 Mn=7, 703 ; 49. 2 (C) PD ! =2. 94 (C) l 1 S 52. 9 232 5. 2 0. 7 110 0. 68 1. 3 Mp=14, 085 ; S 52. 9 (1H) M, =16, 218 ; (1 H) Mn=6, 557 ; PDI=2. 47 233 5. 2 1. 4 110 0. 61 1. 3 Mp=12, 930 ; S 54. 3 (1 H) Mw= 15, 711 ; (1 H) Mn=5, 868 ; PDI=2. 68 234 10. 4 0. 7 110 0. 58 1. 2 Mp=13, 699 ; S 53. 1 ('H) Mw=15, 722 ; ('H) Mn=4, 840 ; PDI=3. 25 235 10. 4 1. 4 110 0. 51 1. 5 Mp=10, 804 ; S 61. 3 ('H) MW=13, 812 ; ('H) 1. 3 Mn=4, 072 ; 54. 1 C) PDI=3. 39 (13C)

Nd: Not determined. aSol. : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g., some insoluble material present.

Table 47 3C NMR Branching Analysis for VTEoS Copolymers of Table 46 Ex. Total Me Me Et Pr Bu Hex+ & eoc Am+ & eoc Bu+ & eoc 206 4. 1 4. 1 0 0 0 0.6 0 0 208 4.3 4.2 0 0 0 0.2 0 0.1 216 14.1 9.2 1.9 0. 6 1.4 1.0 1.9 2.5 222 15.2 9.8 2.5 0. 9 0.0 1.4 1.1 2.1 226 26. 1 17.4 2.6 1.1 1.3 2.4 2.6 5.1 227 32.1 21.3 3.5 2.1 2.2 3.0 3.9 5.2 228 28.0 19.4 2.3 1.6 2.2 2.7 4.0 4. 7 229 35.0 21.7 4.3 2.4 2.0 2.9 4.6 6.6 230 34.5 22.0 4.8 1.8 1.9 3.7 4.0 5.9 231 49.2 28. 3 7. 5 2.2 3.0 4.6 5.7 11. 2 235 54.1 32. 1 8. 1 2.4 2.8 4. 6 7. 2 11.4

Table 48 Analysis of the Spacing (n) between Si and the Copolymer Backbone for Co- polymers of Table 46 Ex. n=0 n=1 n=2 n=3 n=4+ % % % % % 206 53. 5 18. 5 14 14 (n=3+) 208 68.6 18. 5 13. 0 0 0 216 46.8 34.7 18.6 0 0 222 46.2 34.0 19.8 Tracea 0 226 32.1 23.0 22.9 11a 11a 227 27.5 26.9 22.9 11 4a 11 4a 228 13.7 28.9 28.8 14. 3a 14. 3 a 229 26.5 22.1 19. 3 22.0 10. 1a 230 27.5 24.2 27.1 14.0 7. 2a 231 40 20 40 0 0 235 28 22 22 15.5 13.5

Estimate from DEPT.

Examples 236-242 Continuous Process Description: The catalyst and activator solutions were transferred from a dry box to the appropriate feed vessels at the polymerization unit. High pressure liquid chromatography pumps continuously pumped these solutions to the reactor (see Example 186). The VTEoS and the olefin comonomers were mixed with the solvent in the solvent tank. From the solvent tank, the mixture was pumped through a micromotion flow meter by a Pulsa Feeder@ diaphragm

pump. At the exit of the pump, ethylene gas was mixed with the process stream. All the process streams were pumped into the reactor. A back- pressure regulator kept the system in a liquid full mode during the reaction. At the exit of the reactor pressure control device, the reactor effluent was dis- charged into a nitrogen purged collection box. The reactor temperature was controlled either by chilling the incoming solvent and monomer feed or by cooling water going through the reactor jacket. A computer constantly moni- tored the trends and events during the operation.

Examples 236 In a drybox, separate stock solutions of catalyst, and activators were prepared. For the catalyst, 101.7 mg of compound B were dissolved in 100 ml of anhydrous toluene (Aldrich) purified with molecular sieves. For the acti- vator mixture, 306.1 mg of triphenylborane and 435.1 mg of lithium tetrakis (pentafluorophenyl) borate were dissolved in 100 ml of toluene and di- luted with 500 ml of anhydrous cyclohexane (Aldrich). The VTEoS was dried under molecular sieves and mixed to a 5% vol/vol concentration in the solvent feed tank. The polymerization reaction was conducted at 70°C, and 3.10 MPa E pressure. The pumps were started and the reactor was operated for about 60 min prior to collecting the samples. In this example, the residence time was 35 min and produced 18.1 g of polymer recovered from the solution.

Polymer workups: The polymer solution was continuously collected in a 1 liter flask for the entire residence time. At the end of the run, the solution was treated with acetone, filtered and dried at RT and low nitrogen pressure. At the completion of the run, the feed vessels for the catalyst and activators were drained and the remaining volumes measured for catalyst/activator usage for this sample. The polymer had a DSC melting point of 84. 8°C and AHf of 66.6 J/g. The silane was 4.2 % wt of the polymer measured by 1H-NMR, the melt index of the polymer was 1.0, the catalyst efficiency was 455 g/PE/g catalyst, and the VTEoS conversion was 7.25%.

Example 237 For the catalyst, a stock solution of B was prepared by dissolving 39.5 mg of catalyst in 100 mL of anhydrous toluene (Aldrich). For the activator, 159.5 mg of triphenylborane and 211. 9 mg of lithium

tetrakis (pentafluorophenyl) borate were dissolved in 100 ml of anhydrous toluene and 500 mi of anhydrous cyclohexane. These two solutions were transferred to the appropriate feed vessels at the unit. The comonomer was mixed with the solvent in the feed tank to a 5% vol/vol solution. The polymer- zation reaction was conducted at 90C, and 3.10 MPa E pressure. The pumps were started and the reactor was operated for about 60 min prior to collecting the samples. The residence time was 35 minutes and produced 11.5 g of polymer recovered from the solution. Polymer workups: The polymer solution was continuously collected in a 1 liter flask for the entire residence time. At the end of the run, the solution was treated with acetone, filtered and dried at RT and low nitrogen pressure. At the completion of the run, the feed vessels for the catalyst and activators were drained and the remaining volumes measured for catalyst/activator usage for this sample. The silane was 1.79 % wt of the polymer, measured by 1H-NMR, the catalysts efficiency was 777 g/PE/g catalyst, and the VTEoS conversion was 2.35%.

Example 238 For the catalyst, a stock solution of B was prepared by dissolving 108.1 mg of catalyst in 300 mL of anhydrous toluene (Aldrich). For the activator, 148. 3 mg of triphenylborane and 198.1 mg of lithium tetrakis (pentafluoro- phenyl) borate were dissolved in 100 ml of anhydrous toluene and 500 ml of anhydrous cyclohexane. These two solutions were transferred to the appro- priate feed vessels at the unit. The comonomer was mixed with the solvent in the feed tank to a 5% vol/vol solution. The reaction temperature was 70°C, and 3.10 MPa E pressure. The pumps were started and the reactor was op- erated for about 120 min prior to collecting the samples. The residence time was 48 min and produced 11.5 g of polymer recovered from the solution.

Polymer workups: The polymer solution was continuously collected in a 1 liter flask for the entire residence time. At the end of the run, the solution was treated with acetone, filtered and dried at RT and low nitrogen pressure. At the completion of the run, the feed vessels for the catalyst and activators were drained and the remaining volumes measured for catalyst/activator usage for this sample. The VTEoS was 3.30 % wt of the polymer measured by 1H-NMR, melt index of the polymer is 0.4, melting point of the polymer is 103. 4°C, the

VTEoS conversion 5.30%, and the catalyst efficiency was 1413 g PE/g cata- lyst.

Example 239 For the catalyst, a stock solution of B was prepared by dissolving 150.3 mg of catalyst in 600 mL of anhydrous toluene (Aldrich). For the activator, 458.9 mg of triphenylborane and 614.3 mg of lithium tetrakis (pentafluoro- phenyl) borate were dissolved in 100 ml of anhydrous toluene and 634 mi of anhydrous cyclohexane. These two solutions were transferred to the appro- priate feed vessels at the unit. VTEoS was mixed with the solvent in the feed tank to a 5% vol/vol solution. The reaction temperature was 70°C, and 3.10 MPa E pressure. The pumps were started and the reactor was operated for about 120 min prior to collecting the samples. The residence time was 33 min and produced 11.5 g and 4 g of polymer recovered from two consecutive samples. Polymer workups: The polymer solution was continuously collected in a 1 liter flask for the entire residence time. At the end of the run, the solu- tion was treated with acetone, filtered and dried at RT and low nitrogen pres- sure. At the completion of the run, the feed vessels for the catalyst and acti- vators were drained and the remaining volumes measured for cata- lyst/activator usage for this sample. The VTEoS was 13.4 % wt and 3.0 % wt of the polymer for the two samples, respectively as measured by 1H-NMR, the polymer did not flow in the melt index test, its melting point was97. 0°C.

Examples 240 For the catalyst, a stock solution of B was prepared by dissolving 150.3 mg of catalyst in 600 mL of anhydrous toluene (Aldrich). For the activator, 458.9 mg of triphenylborane and 614.3 mg of lithium tetrakis (pentafluoro- phenyl) borate were dissolved in 100 ml of anhydrous toluene and 634 mi of anhydrous cyclohexane. These two solutions were transferred to the appro- priate feed vessels at the unit. VTEoS was mixed with the solvent in the feed tank to a 5% vol/vol solution. The reaction temperature was 70°C, and 3.10 MPa E pressure. The pumps were started and the reactor was operated for about 67 min prior to collecting the samples. The residence time was 33 min and produced 8.7 g, 5.8 g, 9.9 g and 13.7 g of polymer recovered from four consecutive samples. Polymer workups: Each polymer solution was continu- ously collected in a 1 liter flask for the entire residence time associated with

the sample. The solution was later treated with acetone, filtered and dried at RT and low nitrogen pressure. At the completion of the run, the feed vessels for the catalyst and activators were drained and the remaining volumes measured to obtain the catalyst/activator usage in each sample. VTEoS con- tents were 0.625 % wt, 2.47 % wt and 1.85 % wt, of the polymer for samples 1, 3 and 4, respectively. The silane composition was measured by 1H-NMR.

Sample 1 had a melting point of 93°C, a VTEoS conversion of 0.24%, and a catalyst efficiency of 534 g PE/g catalyst.

Example 241 For the catalyst, a stock solution of B was prepared by dissolving 151.5 mg of catalyst in 600 mL of anhydrous toluene (Aldrich). For the activator, 450.1 mg of triphenylborane and 607.1 mg of lithium tetrakis (pentafluoro- phenyl) borate were dissolved in 100 ml of anhydrous toluene and 600 mi of anhydrous cyclohexane. These two solutions were transferred to the appro- priate feed vessels at the unit. The comonomer was mixed with the solvent in the feed tank to a 5% vol/vol solution. The reaction temperature was 70°C, and 3.10 MPa E pressure was used. The pumps were started and the reactor was operated for about 120 min prior to collecting the samples. The resi- dence time was 33 min and produced 51.7 g of polymer recovered in a single sample. Polymer workups: the polymer solution was continuously collected in a 1 liter flask for the entire residence time associated with the sample. The solution was later treated with acetone, filtered and dried at RT and low nitro- gen pressure. At the completion of the run, the feed vessels for the catalyst and activators were drained and the remaining volumes measured to obtain the catalyst/activator usage in each sample. VTEoS content was 9.33 % wt of the polymer, which was measured by 1H-NMR, the melt index was 0.13, the melting point was 106. 9°C, the VTEoS conversion was 10.7% and the catalyst efficiency was 2945 g PE/g catalyst.

Example 242 For the catalyst, a stock solution of B was prepared by dissolving 75.1 mg of catalyst in 600 mL of anhydrous toluene (Aldrich). For the activator, 238.1 mg of triphenylborane and 300.2 mg of lithium tetrakis (pentafluoro- phenyl) borate were dissolved in 100 ml of anhydrous toluene and 600 mi of anhydrous cyclohexane. These two solutions were transferred to the appro-

priate feed vessels at the unit. VTEoS was mixed with the solvent in the feed tank to a 5% vol/vol solution. The reaction temperature was 70°C, and 3.10 MPa E pressure was used. The pumps were started and the reactor was op- erated for about 120 min prior to collecting the samples. The residence time was 70 min and produced 20.8 g, 7.9 g, and 6.9 g of polymer recovered from three consecutive samples. Polymer workups: Each polymer solution was continuously collected in a 1 liter flask for the entire residence time associated with the sample. The polymer solutions were later treated with acetone, fil- tered and dried at RT and low nitrogen pressure. At the completion of the run, the feed vessels for the catalyst and activators were drained and the remain- ing volumes measured to obtain the catalyst/activator usage in each sample.

The % silane contents were 1.31 % wt, 2.23 % wt and 3.11 % wt, for each sample, respectively, which were measured by 1H-NMR. For the second sample, melting point was 109. 2°C, melt index was 0.36, the VTEoS conver- sion was 1.44%, and the catalyst efficiency was 1013 g PE/g catalyst.

Example 243-248 Molecular Weight Control with Hydrogen In a drybox, II was mixed with 2.5 ml of VTEoS and transferred a re- actor inject tube. Triphenylborane (TPB) was mixed with mi of anhydrous toluene and transferred to another reactor injector tube. First, the 250 ml of cyclohexane was transferred to the reactor at RT. Then, the catalyst was injected into the cyclohexane followed by the saturation of the solvent with hydrogen to the desired pressure. The reactor was heated to 70°C and pres- surized with ethylene to 2.41 MPa. The catalyst and VTEoS mixture was in- jected into the reactor and the reactor pressure was raised to 2.76 MPa with ethylene. The reaction was allowed to proceed for 1 h. The polymer was isolated and the dry polymer yield is shown in Table 49, together with the melt index and the VTMoS polymer content measured by 1H-NMR.

Table 49 Ex. Catalyst TPB Hydrogen Polymer Melt Index VTMos m mg) kPa) (g) 9g/10 min) (% wt 243 12.4 206.7 97 6.4 No Flow 2.216 244 12. 7 200. 4 145 6.7 0. 16 2. 409 245 12.8 203. 2 207 11.2 2.4 0. 923 246 11.7 203.3 276 9. 1 11 NA 247 12. 9 200.9 345 13.1 35 NA 248 12. 5 198. 7 152 15.1 4. 7 1. 435

Examples 249-250 In a dry box, the reactor injector tubes were charged with amounts of the catalyst of Example 194 and triphenylborane (cocatalyst), as shown in Table 50. In the catalyst tube, 15 ml of VTMoS was added, and to the co- catalyst tube 10 ml of anhydrous toluene (Aldrich) was added. A 3. 81 reactor was charged with 1200 g of cyclohexane, then the solvent was saturated with hydrogen to the pressure shown in Table 50. The reactor was heated to 70°C, then the catalyst was injected with ethylene, followed by the catalyst (also with ethylene). The ethylene feed was switched to the reactor side port and the reactor pressure was raised completed to 2.76 MPa with ethylene.

The reaction was allowed to proceed for about 3 h. At the end of the run, the polymer was recovered, was washed with acetone, and dried overnight in a vacuum oven under nitrogen purge. The dried polymer yield, the melt index and the silane content are shown in Table 50.

Table 50 Ex. Catalyst Cocatalyst Hydrogen Polymer MI VTMoS m (g) kPa g (wt%) 249 205.8 3.20 138 494 0. 53 3. 74 250 206. 8 3. 21 186 421 0. 40 1.56 Example 251 Preparation of Low Haze Polymer In a drybox, the designated amount of catalyst B or"comparative cata- lyst"1 [a metallocene catalyst, isopropylidene (cyclopentadienyl) (9- fluorenyl) zirconium dichloride] was dissolved in 80 ml of toluene and mixed with 0.5 mi of triisobutylaluminium (Aldrich, 1 M in Hexanes) when the catalyst

was 1, while no triisobutylaluminium was added to the catalyst solutions for B.

The mixture was transferred to a catalyst pump feed vessel. In the drybox, 20 mg of the activator tetrakisperflourinated anilinium borane was dissolved in 5 mi of toluene and the designated amount of purified 1-octene, as shown in Table 51. A 500 ml Autoclave Engineers stirred reactor was preheated to 60°C. Anhydrous cyclohexane (250 ml) was added first to the reactor, fol- lowed by 0.5 ml of triisobutylaluminium scavenger and then by the activator/1- octene mixture. The reactor was pressurized with ethylene to 2.76 MPa. The catalyst was pumped at the rate and duration shown in Table 51. At the end of the run, the amount of catalyst recovered was used to calculate the catalyst injected into the reactor. These quantities are recorded in Table 51, as the catalyst weight. At the end of the run, the polymer was isolated and dried in a vacuum oven.

Table 51

Run No. Catalyst Pumping Rate Pumping Time 1-octene VTEoS Duration Polymer (mg) ml/min min ml ml min 251-1 B (12. 8) 1. 14 70 75 10 70 11. 8 251-2 B (18. 7) 1.25 60 75 0 60 12.1 251-A 1 (2. 0) 0. 80 10 50 0 40 49.1 251-B 1 (17. 5) 1. 30 55 100 0 55 15.8

The polymer characterization by DSC, and 1H-NMR is shown in Table 52. Haze measurements were made on pressed films of 25 ilm thickness.

The haze measurements were done on a HunterLab ColorQuestO XE (dual beam xenon spectrophotometer) using CIELAB color scales and D65 illumi- , nant at a 10° observer angle. All samples were measured in three different areas of the film and the average of three readings was recorded.

Table 52 Run No. Tm AHf moi % wt % mol % wt. % Haze °C J/g octene octene VTEoS VTEoS 251-1 97.4 80.34 1.53 5. 85 0. 693 3. 56 12. 7 225-2 99. 7 80. 24 1.88 7. 12 16. 82 251-A 102. 6 31.1 3.15 11. 51 24. 2 251-B 75. 5 40. 39 5. 04 17. 59. 2

The results show that the ethylene/octene/vinyl silane terpolymer has lower haze than comparative polymers that have higher comonomer content.

Example 252 Preparation of a Crystalline Copolymer of Ethylene and VTEoS.

A sample of copolymer was prepared by dry blending the products of 11 separate polymerizations done in a jacketed 450 mL autoclave using the following procedure. In a drybox 0.0015 g (0.0023 mmol) of B was dissolved in 2.0 mL of dry toluene and loaded into a small metal catalyst addition tube fitted with valves. The catalyst addition tube was attached to the autoclave using a positive nitrogen purge while making the connection.

Li [B (C6F5) 4] (Et2O) n cocatalyst (5.0 mole equiv. per Ni, n 2.5, Boulder Scien- tific) and B (C6F5) 3 catalyst (5.0 mole equiv. per Ni, Sud-Chemie) were pre- dissolved in 2.0 mL of a 1: 1 mixture of toluene and VTEoS, and this solution was added to the remainder of the toluene and VTEoS in a RB flask. The to- tal volume of toluene in the final solution was 292.5 mL, and the total volume of VTEoS in the final solution was 7.5 mL. This solution was transferred from a rubber septum capped RB flask by cannula into the dry autoclave under a nitrogen purge. The autoclave and contents were purged with ethylene by pressurizing to 690 kPa while stirring followed by venting. After 3 cycles of pressurizing and venting, the autoclave was heated to 60°C and pressurized with ethylene to 4.1 MPa. The polymerization was started by opening the lower valve of the catalyst addition tube allowing the Ni catalyst solution to flow into the reactor. The mixture was stirred mechanically at 1200 rpm. After about 1.5 h the reaction was terminated by rapidly cooling the autoclave to room temperature and venting the ethylene. The polymer solution was added to 750 mL of dry MeOH containing several drops of triethylamine in a War- ing@ blender that had been fitted with a nitrogen-purged motor housing. The solvent/solid polymer mixture was filtered on a fritted glass filter and the poly- mer was washed on the filter with three 50 mL portions of anhydrous MeOH.

The solid polymer was then dried in vacuo in an aluminum pan at room tem- perature to constant weight. Run-to-run reproducibility in the 11 polymeriza- tions was good as evidenced by the low standard deviation in polymer

branching: 11.4 1.2 CH3 per 1000 CH2, and weight% VTEoS : 1.51 0.08.

Both values were determined by 1H NMR. The final dry blended polymer sample weighed 208 g (89 kg copolymer per g Ni). Analyses of the blended sample : DSC (second heat, 10°C/min : Tm = 120. 6°C, 130 J/g. GPC (135°C, TCB, RI detector, vs. polystyrene): Mn = 35,000 ; Mw = 70,500 ; PDI = 2.0. MI : 2.7 g/10 minutes (2160 kg, 190°C). H NMR branching: 10.4 CH3 per 1000 CH2. Weight% VTEoS : 1.46.

Example 253 Articles Coated with EthyleneNinvisilane Copolymers The following example demonstrates articles such as metal, glass, wood, paper, ceramic, or thermoset that are partly or completely coated with ethylene vinylsilane copolymers. The articles could be protected by the co- polymer or would find the copolymer useful as an adhesive because of supe- rior adhesion such as for building panels. These polymers show surprisingly good adhesion to the substrates.

The following substrates were prepared for adhesion to the copoly- mers: a) 10 mil thick aluminum foil samples were washed in soap and water followed by acetone washing and drying at ambient conditions. b) 5 mil thick sheets of carbon steel A109 were washed with Bon Ami and water followed by acetone washing and drying at ambient conditions. c) 15 mil samples of copper foil were washed in acetone and dried at ambient conditions. d) 50 mil thick glass microscope slides were washed in soap and water followed by acetone washing and drying at ambient conditions.

The following copolymers were tested for adhesion: a) The polymer of Example 252. b)"SI-LINK"DFDA-5451 from Dow Chemical Corporation, which had a melting point at 110°C.

The samples were prepared by placing 7 g of pellets of were into a 4.08 cm by 10.2 cm by 0.13 cm hollow steel box, the base of which was opened to the substrate. The assembly was heated in a press for 1 min at 230°C at atmospheric pressure. The press pressure was raised rapidly to 172

MPa and held for 1 min. The assembly was cooled to 23°C within 3 min. 1- 2.5 cm wide strips were tested for adhesion at 5.08 cm/min using a 180° pull angle. The copolymer of Example 252 had a 4375 N/m pull force with glass, 2540 N/m with aluminum, 70 N/m with carbon steel, and 210 N/m with copper.

DFDA-5451 had a pull force of 700 N/m with glass, 88 N/m with carbon steel, 175 N/m with aluminum, and 88 N/m with copper.

Example 254 Peel Strength of Articles Coated with EthyleneIVinylsilane Copolymers The following example shows crosslinked articles, meaning the co- polymer has been crosslinked through the alkyoxysilane groups. The co- polymers of the application show a surprisingly larger improvement of their thermomechanical properties given their somewhat higher melting point and slightly higher silane content.

The following copolymers were tested for maximum temperature: a) The copolymer of Example 252. b)"Si-LINK"DFDA-5451 from Dow Chemical Corporation. This co- polymer had a melting point at 110°C and a silane content of 1.3% by 13C NMR.

The samples were prepared by melt blending 53 g of each copolymer with 2.5 g of an 3% concentrate of dibutyltin dilaurate in a 112°C melting point ethylene copolymer and with 0.5 g of IRGANOXO 1010 antioxidant. Blending was conducted in a Hake@ batch blender at 75 rpm, 200°C, and 10 minutes.

The resulting product was stored under nitrogen until further processed. A sample (12 g) of the above compounded copolymer was pressed through a polyester fabric having a box pattern wave and a density of 217 g/m2 The press conditions were 200°C, with a 1-min preheat and 1-min hold at 172 MPa pressure. The resulting disc was cut in half and the halves pressed against themselves except for a 2.5 cm wide zone on the edge. The assem- bly was exposed to 70°C water for 24 h to effect crosslinking within the com- pounded polymer. The resulting product was cut into 2.54 cm wide strips. A 1500 g or 400 g weight was hung from one unsealed edge and the top was fixed to a support. This setup created a 180° peel assembly which was

placed in an oven. The temperature was ramped up from 25°C at 1°C per mi- nute. The temperature at which the peel failed was noted. The peel for the sample based upon the copolymer of Example 252 survived up to 135°C and 105°C for the 400 g and 1500 g weight respectively. The peel for the DFDA- 5451 sample survived up to 100°C and 83°C for the 400 g and 1500 g weight respectively.

Example 255 Films and Sheets of EthvleneNinvlsilane Copolmers A 53 g sample of the copolymer of Example 252 was melt blended with 2.5 g of a 3% concentrate of dibutyltin dilaurate in an ethylene copolymer having a 112°C melting point. Blending was conducted in a Hake@ batch blender at 75 rpm and 200°C for 10 minutes. The resulting product was stored under nitrogen until further processed. A sample of 4 g of the above compounded copolymer was pressed into a film approximately 0.13 mm thick.

The press conditions were 190°C, with a 1-min preheat and 1-min hold at 172 MPa pressure. The film was exposed to 70°C water for 24 h. Another film was made without dibutyltin dilaurate. The tensile yield strength at 25°C was 9.38 MPa and 9.65 MPa for the sample without tin and with tin respectively.

The tensile modulus at 25°C between 0% and 2% strain was 228 MPa and 296 MPa for the sample without tin and with tin respectively. The tensile properties at 100°C could not be tested for the samples without tin because the samples were too close to their melting points and started to flow. The samples containing tin had an elongation at 100°C ofi 500300% and tensile secant modulus of 2. 1690 kPa.

Example 256 Synthesis of 1 H, 1 H. 2H, 2H-Perfluoro-n-decyl-diethoxyvinylsilane CF3 CF2)7CH2CH2Si(OEt)2(CH=CH2) The Grignard reagent prepared from 50.0 g (0. 087 mol) of 1,1, 1,2, 2,3, 3,4, 4,5, 5,6, 6,7, 7,8, 8-heptadecafluoro-1-iododecane and 4.2 (0.18 mol) of magnesium in 300 mi of ether was added dropwise to the solution of 49.73 g (0. 26 mol) of VTEoS in 50 mi of ether at-70°C. The reaction mixture was allowed to warm up to RT and was stirred overnight. The solvent was removed under vacuum and the residue was extracted with 400 ml of hex- anes. The extract was concentrated in vacuum and distilled. Yield of 1 H, 1 H, 2H, 2H-perfluoro-n-decyldiethoxyvinylsilane was 18.84 g (36.53%) as a colorless liquid with b. p. 87-90°C/1 Pa.'H NMR (CDCI3) 0.65-0. 72 (m, 2H), 1.05 (t, 6H, J=7. 0Hz), 1.90-2. 05 (m, 2H, ) ; 3.60 (q, 4H, J=7. 0Hz), 5.70-6. 10 (m, 3H). 13G NMR (CDCI3) 0.00 (s) ; 15.39 (s), 22.39 (m); 55.98 (s), 113.53- 116. 08 (m), 128.89 (s), 133.77 (s). 9F NMR (CDCI3) 81.85 (m), 116.98 (m), 122.47 (m), 122.65 (m), 124.48 (m), 124.03 (m), 124.30 (m), 126.95 (m). 29Si NMR (CDC13)-22. 38. Anal. Calcd. for C1H17E17O2Si : C, 32.44 ; H, 2.89 ; F, 54.52. Found: C, 32.25 ; H, 2.74 ; F, 54.60.

Examples 256-261: Copolymerization of 1 H, 1 H, 2H, 2H-Perfluorodecvldiethoxv-vinvlsilane, CF3(CF2)27CH2CH2Si(OEt)2(CH=CH2), with Ethylene Copolymerizations were carried out utilizing B, and EE. The polymer- zation results are presented in Table 53. Vials were loaded in a nitrogen at- mosphere glove box with the indicated amount of the catalyst, cocatalyst, co- monomer and p-xylene. The vials were placed in a tube, which was heated to the indicated temperature and pressured with ethylene to the indicated pres- sure. After 18 h, the resulting copolymers were stirred with methanol, washed twice with methanol and washed one time with ether. The polymer samples were dried under vacuum 0.1 Pa overnight.

Table 53: Ethylene copolymrizationw with fluoroalkyl-functionalized vinylsilane. Example Catalyst Cocat. Comonomer Temp. ( Press. Yield Comon. m. p. M. W. Number (mmol) (mi) OC) (MPa) (g) Incorp. (°C) (Hf) weight% 256 B (0. 0005 20 eq 0. 5 80 4. 14 1. 41 1. 18 103. 28 49, 980 mmol) B (C6F5) 3 (120. 4) Lit CF 4 267 EE 1 ml 6. 42% 0. 5 60 4. 14 6. 83 0. 17 94. 28 164, 611 (0. 02 MMAO in (56. 61) mmole) heptane 258 EE 1 ml 6. 42% 1 60 4. 14 7. 05 2. 63 101. 98 136, 364 (0. 02 MMAO in (34. 23) mmole) heptane 259 EE 1 ml 6. 42% 2 60 4. 14 6. 18 1. 29 101. 97 162, 929 (0. 02 MMAO in (18. 61) mmole) heptane 260 B 1 eq 0. 5 60 4. 14 1. 64 0. 78 117. 03 58, 895 (0. 0015 (HNMe2Ph) (120. 1) moll)) 4 261-H 10 eq 1 100 4. 14 4. 79 1. 24 123. 48 24, 935 t47. 3) The polymer of eample 261 had a hexadecane contact angle of 37.1~0.22° (average of three readings) indicating migration of the<BR> fluoro groups to the surface.

Examples 262-266 Preparation of Amorphous and Low Crvstallinity Copolymers R=Et, JJ; R=i-Pr, KK

R=i-Pr, R'=H, LL; R=Et, R'=H, MM Polymerizations were done in a jacketed 450 mL autoclave. In a dry- box Li [B (C6F5) 4]. (Et2O) n cocatalyst (4.1 mole equiv. per Ni, n 2.5, Boulder Scientific) was dissolved in 2. 0 mL of anhydrous chlorobenzene and added to the VTMoS comonomer (stored over activated 5A molecular sieves and passed through activity 1 basic alumina immediately before use). B (C6F5) 3 catalyst (5.2 mole equivalents per Ni, Sud-Chemie) was added to the mix- ture and the solution was diluted with anhydrous toluene to give a total vol- ume of 150 mL. This solution was transferred from a rubber septum capped RB flask by cannula into the dry autoclave under a nitrogen purge. In a dry- box, the Ni catalyst was dissolved in 2.0 mL of dry toluene and loaded into a small metal catalyst addition tube fitted with valves. The catalyst addition tube was attached to the autoclave using a positive nitrogen purge while making the connection. The autoclave was purged with ethylene, and then heated to the reaction temperature and pressurized with ethylene. The polymerization

was started by opening the lower valve of the catalyst addition tube allowing the Ni catalyst solution to flow into the reactor. The mixture was stirred me- chanically at 1200 rpm. Ethylene uptake was monitored and when ethylene uptake had ceased or slowed considerably, the reaction was terminated by rapidly cooling the autoclave to room temperature and venting the ethylene.

Reaction times were typically about 2 h. The polymer solution was added to 750 mL of dry MeOH containing several drops of triethylamine in a Waring@ blender that had been fitted with a nitrogen-purged motor housing. Amor- phous or very low crystallinity polymers typically precipitated on the side of the glass blender. The toluene/MeOH mixture was decanted from the polymer and the polymer was redissolved in 150 mL of toluene containing several drops of triethylamine. Inverse precipitation of the polymer was then done by slow addition of 750 mL of anhydrous MeOH to the stirring solution in the blender. The toluene/MeOH mixture was decanted from the reprecipitated polymer, and the polymer was dissolved in 150 mL of anhydrous diethyl ether.

The ether solution was transferred to a tared round bottom flask and the ether was removed in vacuo on a rotary evaporator. The precipitated polymer was further dried in vacuo at RT in the flask until constant weight indicated the re- moval of all solvent. If initial precipitation of the polymer in the blender gave a solid the workup procedure was modified. After the redissolution and inverse precipitation in the blender, the solvent/solid polymer mixture was filtered on a fritted glass filter and the polymer was washed on the filter with three 50 mL portions of anhydrous MeOH. The solid polymer was then dried in vacuo in an aluminum pan at room temperature to constant weight. Catalysts JJ, KK, LL, and MM used in these experiments were prepared by reaction of Ni (CH2SiMe3) 2 (py) 2 with the appropriate ligand analogous to the preparation of catalyst B (Example 102). Polymer analyses: DSC was done with two heats from-20°C to 175°C at 10°C/min with a controlled cooling of 10°C/min between the two heats. Except as noted, the data from the second heat was recorded (Table 54). For samples which showed a melting transition on the first heat but not on the second heat, the first heat data was recorded. Mo- lecular weight was determined by GPC in 1,2, 4-trichlorobenzene at 135°C vs. polystyrene standards using an RI detector. As noted in Table 54, in some cases absolute molecular weights were determined by dual detection GPC (RUviscosity) in 1,2, 4-trichlorobenzene using the universal calibration method.

Vinylsilane incorporation was determined by integration of the-Si (OR) 3 peaks in the 1H NMR. MI (g/10 minutes) was determined at 190°C with a 2.16 kg weight Table 54.<BR> <P>Amorphous and low crystallinity copolymers of ethylene and VTMoS. Ex. Cat. No. Temp Ethylene Silane Yield (g) mi Mw'H NMR silane No. (°C) (MPa) [vol%] [kg copoly- [PDI] branching incorp Comment [Amount mer (CH3 per (mole%) (, umol)] per g Ni] 1000 CH2) 262 JJ 80 2. 07 VTMoS 10. 5 g 6. 8 64, 500 61 3. 8 opaque, [14. 3] [25] [12. 5] [2. 1] Tm=43 °C 14. 4 J/g 263 JJ 90 2. 07 VTMoS 10. 4 g 39, 700 65 8. 4 clear viscous [28. 5 50 6. 2) 2. 1 a II uid 264 JJ 90 3. 45 VTMoS 8. 3 g 57 5. 2 clear viscous [28. 5] [50] [5. 0] liquid 265 KK 80 2. 07 VTMoS 13. 3 g NF 231, 500 91 1. 2 opaque, [28. 5] [25] [7. 9] [2. 5] Tm=41 °Cb 2. 7 J/g aAbsolute moelcular weights determiend by GPC in 1,2,4-trichlorobenzene at 135 °C using dual detection (RI/viscosity) and the<BR> universal calibration method.<BR> <P>5 bDSC data is from the first heat

Examples 266-272 Preparation of Amorphous and Low Crvstallinity Copolymers of Ethylene and VTMoS or VTEoS.

Polymerizations were carried out identically to Examples 1-4 except for the following changes: the Li [B (C6F5) 4] (Et2O) n cocatalyst was dissolved di- rectly in the comonomer without the use of chlorobenzene, the amount of B (C6F5) 3 cocatalyst was 5.0 mole equiv. per Ni, in examples 269-272 the amount of Li [B (C6F5) 4]. (Et2O) n cocatalyst was 5.0 mole equiv. per Ni, and in example 272 the solvent was cyclohexane instead of toluene. The results are shown in Table 55.

Table 55<BR> Amorphous and low crystallinity copolymers of ethylene and VTMoS or VTEoS. Ex. Cat. No. Temp Ethylene Silane Yield (g) mi Mw'H NMR silane Comment No. [Amnt. (°C) (MPa) [kg copoly-branching incorp (, mol)] [vol%] mer [PDI] (CH3 per (mole%) per g Nil 1000 CH2) 266 KK 90 2. 07 VTMoS 8. 9 g NF 134, 700 99 1. 4 opaque, [14. 5] [25] [10. 5] [2. 0] Tm=42°Cb 0. 6 J/g 267 MM 70 2. 07 VTEoS 27. 3 g NF 47, 200 33 8. 0 white solid [29. 5] [50] [15. 8] [2. 2] a Tm=40°Cb 12. 0 J/g 268 MM 90 2. 07 VTEoS 24. 2 g 30, 400 61 9. 4 clear viscous [22. 4] [50] [18. 4] [2. 1] a liquid 269 LL 90 2. 07 VTEoS 25. 7 g 38, 900 49 7. 6 hazy high vis- [22. 3] [50] [19. 6] [2. 1] a cosity gel 270 LL 80 2. 07 VTEoS 28. 9 g 29 57, 800 44 3. 3 solid [11. 2] [25] [44. 0] [2. 2] a Tm=66°C 53 J/g 271 LL 80 1. 38 VTEoS 10. 3 g 39, 600 56 4. 9 white solid [11. 2] [25] [15. 6] [2. 1] broad melting 272 KK 120 3. 45 VTEoS 2. 0 g 123, 600 132 0. 36 clear rubber [18] [10] [1. 9] [1. 9] aAbsolute moelcular weights determined by GPC in 1,2,4-trichlorobenzene at 135 °C using dual detection (RI/viscosity) and the<BR> universal calibration method.<BR> bDSC data is from the first heat Table 56 3C NMR branching analysis for examples from Tables 54 and 55. Ex. Total Me Me Et Pr Bu Am+ & EOC 262 61. 7 40. 8 4. 5 3. 6 0. 0 11. 9 263 54.6 51.9 0.7 0.7 0.0 2. 1 265 47.0 44.7 0.6 0.5 0.0 1.5 268 53.3 32.6 2.8 3.6 8.2 7.8 269 50.4 35.8 2.0 2.8 2.3 6.5 270 43.2 31.3 2.4 2.3 2.6 4.7

Table 57 13C NMR analysis of the number of (CH2) n groups between the Si and the co- polymer backbone for examples from Tables 54 and 55. Example n = 0 (%) n = 1 (%) n = 2 (%) n = 3 (%) n = 4+ (%) 262 12.2 27.1 13.0 12. 6 35.1 263 17. 7 15.2 14.1 14.0 39.0 265 21.8 14. 2 13. 5 14.9 35.6 268 20.5 19.6 15. 3 9.3 35.3 269 19. 5 21.7 14. 2 10.3 34.3 270 21. 5 23. 3.3 123 8.1 34.8

Example 273 Preparation of NN, and polymerization with high VTMoS incorporation

NN Ad = adamantyl A sample of 0. 5 g (0.003 mol) of [bis (1,1- dimethylethyl) phosphino] methyl lithium was added to the solution of 0.53 g (0.003 mol) of adamantyl isocyanate in 20 ml of THF. After stirring the reac- tion mixture for 12 h, 0.41 g (0.003 mol) of nickel allyl chloride dimer was added in one portion. After 3 h, the solvent was removed under vacuum, and

the residue redissolved in ethyl ether and filtered through Celite0. Ethyl ether was then removed in vacuum. The yield of NN was 1.07 g (73%) as brown powder. 1H-NMR (CD2CI2) 0.5-1. 3 (broad signals, 18H, tert-Bu), 1.5-2. 8 (broad signals, 17H, Adamantyl-H and P-CH2-), 3.40-5. 00 (broad signals, al- lyl-protons). 31 P-NMR (CD2CI2) 48. 58 ppm Copolymerization of ethylene with 1 H, 1 H, 2H, 2H-perfluoro-n- decylvinyidimethoxysilane under the conditions of Table 53 with 0.01 mmol of NN and 20 equivalents of B (C6F5) 3, gave a polymer with a melting point of 136°C, molecular weight of 758,000, and incorporation of the comonomer of 18. 65 % by weight.

Examples 273-311.

PMAO-S1 was obtained from Akzo Nobel Inc. Sylopol from Grace (Davison 948) was calcined at 500°C in a quartz tube under nitrogen for 12 h and transferred to a drybox after cooling. MAO supported on silica (SMAO, 2409) was used as received from Grace. The ligands and transition metal complexes shown below are used in the following examples. The syntheses of 00-RR is described below. The synthesis of 4-allyl-2, 6-Me2-aniline is re- ported in Elliott, M.; Janes, N. F. J. Chem. Soc. (C), 1967,1780-1782. SS and TT are a-diimines and/or Ni complexes the same as or similar to those described in US6034259 and references therein, and US6103658, and these a-diimines and/or Ni complexes are made by methods similar to those de- scribed therein.

00 PP QQ

RR SS TT Example 273 Synthesis of 00 To a 300 mL RB flask was added 3.0 g of acenapthoquinone (182. 17 g/mol, 0.01647 mmol) and 200 mL of toluene and 6.22 g of 4-allyl-2, 6-Me2- aniline (161.24 g/mol, 0. 03858 mmol, 2.3 equiv) and a couple of small crystals of p-toluenesulfonic acid monohydrate. The reaction was heated to reflux using a Dean-Stark trap to remove the water generated in the reaction. The solution was heated for several days. Another portion of 4-allyl-2, 6-Me2- aniline was added to drive the reaction to completion. The solvent was re- moved under vacuum and the product was precipitated from methanol.'H NMR (CeDe) : 7.9 (d, 2H, ACN); 7.4 (t, 2H ACN) ; 7.0 (s, 4H, m-NAr); 6.8 (d,

2H, ACN); 6.1 (m, 2H, CH2CH=CH2) ; 5.1 (m, 4H, CH2CH=CH2) ; 3.4 (d, 4H, CH2CH=CH2) ; 2.1 (s, 12H, o-Me).

Example 274 Synthesis of PP NiBr2 (DME) (0.627 g, 308.65 g/mol) and bis [4-allyl-2, 6-dimethylphenyl- imino] acenapthequinone (1.0 g, 468.63 g/mol) were combined in a 100 mL RB flask with 40 mL of dichloromethane. The solution was stirred overnight.

The solvent was removed under vacuum and the residue was slurried in pentane and filtered. The solid was recrystallized from dichloromethane and pentane. The brick-red solid was isolated by filtration and dried under vac- uum. Yield : 0.968 g.

Example 275 Synthesis of QQ Ni (acac) 2 (0.521 g, 256.91 g/mol) and bis [4-allyi-2, 6- dimethylphenylimino] acenapthequinone (1. 0 g, 468. 63 glmol) were combined in a 100 mL RB flask with 40 mL of dichloromethane. The solution was stirred overnight. The solvent was removed under vacuum and the residue was dis- solved in pentane and recrystallized at-30°C. The dark yellow solid was iso- lated by filtration. Yield : 1. 028 g.

Example 276 Synthesis of RR A 100 mL RB flask with 30 mL of pentane was cooled to-30°C. The flask was charged with {pyridine} 2Ni (CH2SiMe3) 2 (0.438 g, 1.12 mmol, 391.32 g/mol) and bis [4-allyl-2, 6-dimethylphenbylimino] acenapthequinone (1.07 mmol, 0.5 g, 468.63 g/mol). Added 20 mL of pentane and chilled to-30°C.

The solution was stirred for 4 h and the solvent is removed under vacuum.

Yield : 0.652 g of dark blue solid.

1H NMR (C6D6) : 7.65 (d, 2H, ACN); 7.14 (s, 4H, m-NAr); 6. 85 (d, 2H, ACN) ; 6.58 (t, 2H, ACN); 6.15 (m, 2H, CH2CH=CH2); 5.2 (m, 4H, CH2CH=CH2) ; 3. 45 (d, 4H, CH2CH=CH2) ; 2.38 (s, 12H, o-NAr); 1.9 (br s, 4H, NiCH2) ; 0.21 (s, 18H, SiMe3).

Example 277 Synthesis of Catalyst A 0.5 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 7 g of toluene and 17 mg of PP. The sample vial was capped and me- chanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 30 min. Yield : 0.490 g of dark blue solid.

Example 278 Synthesis of Catalyst A 0.5 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 7 g of toluene and 18 mg of QQ. The sample vial was capped and me- chanically shaken for 1 h. The slurry was filtered and rinsed 3 times with tolu- ene (10 mL) followed by 3 times with pentane (10 mL) and dried under vac- uum for 30 min. Yield : 0.505 g of dark purple solid.

Example 279 Synthesis of Catalyst A 0.5 g sample of dried Sylopol 948 (calcined at 500°C under nitrogen) was added to a vial with 7 g of toluene, 26 mg of B (C6F5) 3 and 2 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 15 min. The isolated solid was added to a vial with 7 g of toluene and a sample of RR (0.025 mmol, 17 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 15 min. Yield : 0.50 g of dark purple solid.

Example 280 Synthesis of Catalyst A 0.3 g sample of PMAO-S1 (Akzo Nobel, prefiltered to remove any solids) was added to a vial with 7g of toluene and 8 mg of A (635.06 g/mol).

The vial was occasionally shaken over 30 min. The sample was filtered and the filtrate was added to 0.5 g of Sylopol 948 (calcined at 500°C under nitro- gen) in a vial. The sample vial was capped and mechanically shaken for 1 h.

The slurry was filtered and rinsed 3 times with toluene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 30 min. Yield : 0.556 g of solid.

Example 281 Synthesis of Catalyst A 0.25 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 5 g of p-xylene and 8 mg of A (635 g/mol). The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with p-xylene (10 mL) followed by 3 times with pentane (10 mL) and dried un- der vacuum for 10 min. Yield : 0.239 g of dark purple solid.

Example 282 Synthesis of Catalyst A 0.25 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 5 g of p-xylene and 18 mg of TT. The sample vial was capped and me- chanically shaken for 1 h. The slurry was filtered and rinsed 3 times with p- xylene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 10 min. Yield : 0.230 g of dark purple solid.

Example 283 Synthesis of Catalyst A 0.3 g sample of PMAO-S1 (Akzo Nobel, prefiltered to remove any solids) was added to a vial with 7g of toluene and 18 mg of TT. The vial was occasionally shaken over 30 min. The sample was filtered and the filtrate was added to 0.5 g of Sylopol 948 (calcined at 500°C under nitrogen) in a vial.

The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with toluene (10 mL) followed by 3 times with pen- tane (10 mL) and dried under vacuum for 30 min. Yield : 0.549 g of solid.

Example 284 Synthesis of Catalyst A 0.5 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 6 g of toluene and a 1.0 g aliquot from a 10.0 g toluene solution of 104 mg of SS and 64 mg of Ni (acac) 2 (256.91 g/mol). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and

rinsed 3 times with toluene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 30 min. Yield : 0.480 g of dark purple solid.

Example 285 Synthesis of Catalyst A 0.6 g sample of PMAO-S1 (Akzo Nobel, prefiltered to remove any solids) was added to a vial with 6 g of toluene and a 1.0 g aliquot from a 10. 0 g toluene solution of 104 mg of SS and 64 mg of Ni (acac) 2. The sample vial was capped and mechanically shaken for 40 min. The sample was filtered and the filtrate was added to 1.0 g of Sylopol 948 (calcined at 500°C under nitrogen) in a vial. The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) fol- lowed by 3 times with pentane (10 mL) and dried under vacuum for 30 min.

Yield: 1.330 g of blue-green solid.

Example 286 Synthesis of Catalyst A 0.25 g sample of dried Sylopol 948 (calcined at 500°C under nitro- gen) was added to a vial with 6.9 g of toluene, 13 mg of B (C6F5) 3 and 2 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 1 h.

The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 30 min. The isolated solid was added to a vial with 7 g of toluene and a sample of B (0. 0123 mmol, 8 mg). The sample vial was capped and mechanically shaken for 30 minutes.

The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 15 min. Yield : 0.212 g of dark solid.

Example 287 Synthesis of Catalyst A 0.25 g sample of dried MS13-1. 1 (calcined at 500 °C under nitrogen) was added to a vial with 6.9 g of toluene, 13 mg of B (C6F5) 3 and 2 drops of NMe2Ph. The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 30 min. The isolated solid was added to a vial with 7 g of toluene and a sample of B (0. 0123 mmol, 8

mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 15 min. Yield : 0.235 g of dark solid.

Examples 288-311 General Polymerization Procedure In a drybox, a glass vial was loaded with a supported Ni catalyst. A solution of cyclohexane and VTEoS was added and the glass insert was then capped and sealed in a tube. Outside of the drybox, the tube was placed un- der ethylene and was shaken mechanically at the temperature indicated for about 16 h. The resulting reaction mixture was mixed with methanol (with a small amount of triethylamine, approximately 0.1 vol%), filtered, repeatedly washed with methanol and the solid polymer dried under vacuum at room temperature for 24 to 48 h. Results are given in Tables 54-57.

Table 54 VTEoS/Ethvlene Copolvmerization Ex. Ex. # for Cata-mmol Temp Yield (g) Mole% M. W. Iyst (wt. mg) Nia (°C) sVTEoS (by 1H NMR) 28 277 (20) 0. 001 60 4. 913 0. 39 Mw 17, 895 8 Mn=24, 755 28 278 (20) 0. 001 60 5. 299 0. 58 MW=162, 603 9 Mn=3O, 808 9 29 279 (20) 0. 001 60 1. 843 0. 25 MW=143782O O Mn=36, 211 29 277 (20) 0. 001 75 3. 68 0. 98 MW=115, 560 1 M, =21, 345 29 278 (20) 0. 001 75 3. 437 0. 97 MW=121, 170 2 Mn= 19, 055 29 279 (20) 000175tJ61093M=84, 885 3 Mn=17, 094 Conditions : 9mL cyclohexane, 1mL VTEoS, 4.1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Table 55 VTEoS/Ethylene Copolymerization Ex. Ex. # for Cata-mmol VTEoS Yield (g) Mole% VTEoS M. W. Iyst (wt. mg) Nia (mL) (by 1H NMR) 29 280 (40) 0. 001 1. 0 2. 098 0. 39 MW=157, 903 4Mn=33, 499 29 280 (40) 0. 001 1. 5 1. 741 0. 57 Mw=160, 207 5 Mn=31, 936 29 280 (40) 0. 001 2. 0 1. 605 0. 74 Mw=129, 373 6 Mn=26, 653 29 281 (20) 0. 001 1. 0 2. 365 0. 38 Mw=168, 824 7Mn=33, 507 29 281 (20) 0. 001 1. 5 1. 869 0. 61 MW=156, 700 8 Mn=24, 815 29 281 (20) 0. 001 2. 0 1. 942 0. 75 MW=150, 311 9Mn=30, 841 Conditions: Solvent is cyclohexane, solution volume is 10 mL, 75 °C, 4.1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Table 56 VTEoS/Ethylene Copolymerization Ex. Ex. # for Cata-mmoi Temp Yield (g) Mole% VTEoS M. W. lyst (wt. mg) Nia (°C) (by'H NMR) 30 282 (20) 0. 001 60 6. 223 0. 52 MW=192, 442 0Mn=38, 688 30 281 (20) 0. 001 60 4. 868 0. 14 Mw=266, 443 1 Mn=38, 319 30 283 (40) 0. 001 60 3. 414 0. 66 MW=226, 549 2 Mn=38, 062 30 280 (40) 0. 001 60 4. 096 0. 13 Mw=222, 978 3Mn=34, 190 30 282 (20) 0. 001 75 1. 912 0. 25 Mw 175, 506 4 Mn=28, 304 30 281 (20) 0. 001 75 3. 563 0. 18 MW=201, 037 5 Mn=35, 019 30 283 (40) 0. 001 75 1. 972 0. 89 MW=192, 916 6 Mn=29, 688 30 280 (40) 0. 001 75 2. 889 0. 24 M, = 190, 515 7 Mn=26, 383 30 284 (20) 0. 001 75 2. 81 0. 36 Mu=141, 792 8 Mn=32, 587 30 285 (40) 0. 001 75 1. 199 1. 74 Mu=124, 094 9 Mn=32, 098 Conditions: Solvent is cyclohexane, solution volume is 10 mL, 75 °C, 4. 1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Table 57<BR> <BR> VTEoS/Ethvlene Copolymerization

Ex. Ex. # for Cata-mmol Temp Yield (g) Mole% VTEoS M. W. I lyst (wt. mg) Nia (°C) (by'H NMR) 31 286 (20) 0. 001 75 1. 876 0. 37 MW=125X440 0 Mn=26, 682 31 287 (20) 0. 001 75 1. 395 0. 89 Mw=96, 857 1 Mn=16, 000 Conditions : 9mL cyclohexane, 1mL VTEoS, 4.1 MPa, 16h. a Theoretical maximum of nickel on supported catalyst.

Example 312 Synthesis of Catalyst A 0.5 g sample of SMAO (12 wt. % AI) was added to a vial with 6.9 g of toluene and C (0.025 mmol, 13 mg). The sample vial was capped and me- chanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and dried under vacuum for 1 h. Isolated 0.505 g.

Example 313 Synthesis of Catalyst A 0. 5 g sample of SMAO (12 wt. % Al) was added to a vial with 6. 9 g of toluene and D (0.025 mmol, 35 mg). The sample vial was capped and me- chanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and dried under vacuum for 1 h. Isolated 0.529 g.

Examples 314-324 Polymerizations The catalysts in Examples 313 and 314 were used in copolymeriza- tions. The results are presented in Tables 58 and 59.

Table58 VTMoS/Ethylene Copolymerization Ex. Ex. # for Temp Pres-VTMoS Yield Mole% M. W. Catalyst (°C) sure (mL) (g) VTMoS (MPa) (by'H NMR) 31 312 75 4. 1 1 2. 589 0. 40 Mw=149, 22 4 6 Mn=17, 759 31 312 75 4. 1 2 1. 773 0. 43 Mw=120, 85 5 5 Mn=22, 764 31 312 60 4. 1 1 2. 134 0. 61 Mw=233, 79 6 6 Mn=35, 108 31 312 60 4. 1 2 2. 757 N. D. Mw=258, 33 7 7 Mn=35, 377 31 312 60 2. 7 1 2. 131 0. 05 Mw=281, 91 8 5 Mn=27, 300 31 312 60 2. 7 2 3. 321 0. 31 Mw=279, 59 9 9 Mn=30, 742 32 312 90 4. 1 1 2. 321 0. 81 Mw=104, 64 0 2 Mn=10, 174 32 312 90 4. 1 2 4. 552 1. 32 Mw=102, 92 1 9 Mn=13, 930

Conditions: solvent = cyclohexane, solution volume is 10 mL total, catalyst weight is 20 mg, 0.001 mmol of Fe is the theoretical maximum of iron on the supported catalyst, 16h.

Table 59 VTEoS/Ethylene Copolymerization in Glass Vials

Ex. Ex. # for Solvent Monomer Yield Mole% M. W. Catalyst (g) VTEoS (by 1H NMR) 322 313 cyclohex-VTEoS 2. 75 0. 12 Mw=65, 681 ane (0. 5mL) 2 Mn=10, 130 (9. 5mL) 323 313 cyclohex-VTEoS 3. 64 0. 22 Mw=96, 211 ane (0. 5mL) Mn=10, 177 (9. 5mL) 324 313 methylcy-VTEoS 2. 12 0. 39 Mw=160, 37 clohexane (5mL) 8 3 (5mL) Mn=23, 368 Conditions: 90°C, 2.73 MPa, 16h, catalyst weight is 20 mg, 0.001 mmol of Fe is the theoretical maximum of iron on the supported catalyst.

Example 325 Synthesis of Supported Catalyst A 1.5 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 7 g of toluene and 133 mg of SS (1437 g/mol). The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with toluene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 30 min. Yield : 1.503 g of dark solid.

Example 326 Synthesis of Supported Catalyst A 1.50 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 7 g of toluene and 50 mg of A. The sample vial was capped and me- chanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 30 min. Yield : 1.441 g of dark solid.

Example 327 Synthesis of UU Ni (acac) 2 (0.77 g, 256.91 g/mol), bis (mesitylimino) acenapthequinone (1.25 g, 416.56 g/mol) and NaBF4 (0. 33 g, 109.79) were combined in a 50 mL RB flask with 20 mL of dichloromethane. The solution was transferred to a 300 mL round bottom flask with 150 mL of methanol. The solvent was re- moved under vacuum and toluene was added to the residue. The solution was filtered and white crystalline solid was recovered on the filter. The tolu- ene was removed from the filtrate to recover 1.564 g of golden-brown solid. A sample was submitted for 19F NMR and there was no indication of a 19F reso- nance. Crystals were grown by slow evaporation of dichloromethane. An X- ray crystal structure analysis indicated the structure shown as UU.

Example 328 Synthesis of Supported Catalyst A 1.50 g sample of SMAO (Grace 2409,14wt. % AI) was added to a vial with 7 g of toluene and 52 mg of UU. The sample vial was capped and me- chanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) followed by 3 times with pentane (10 mL) and dried under vacuum for 30 min. Yield : 1.434 g of dark solid.

Examples 329-331 Copolymerization of Ethylene with VTEoS All polymerizations were done in a 450 mL jacketed autoclave at 75°C, 4.14 MPa ethylene in cyclohexane. A solution of VTEoS (22.5 mL) in anhy- drous cyclohexane (102.5 mL) was transferred by cannula to the dry nitrogen purged autoclave from a septum capped round bottom flask. In a drybox, the

solid supported catalyst was added as a slurry in 2 mL of cyclohexane to an addition tube consisting of a short piece of 0.6 cm ID tubing with pressure fit- tings at both ends and a valve at the bottom. A 50 mL metal bomb with Gvalves and pressure fittings at both ends was attached to the top of the tube containing the catalyst, and it was charged with 50 mL of additional cyclohex- ane. All of the valves were closed, and this addition apparatus was con- nected to the autoclave at the bottom and an ethylene line at the top while purging with nitrogen. The autoclave was purged by three successive pres- sure/vent cycles to 0.35 MPa ethylene. The autoclave was then heated to 75°C and the ethylene pressure was adjusted to 3.86 MPa. The reaction was initiated by pressure injecting the catalyst from the addition tube with 4.14 MPa ethylene. The pressure was maintained at 4.14 MPa during the polym- erization and the reaction was stopped by cooling the autoclave rapidly to RT and venting the excess ethylene. The polymer slurry was poured into 750 mL of anhydrous MeOH in a blender. After mixing for several minutes the mixture was filtered on a sintered glass fritted filter. The polymer was washed on the filter with three 50 mL portions of anhydrous methanol, and the polymer was dried overnight in vacuo at RT. Reaction details and characterization are summarized in Table 60.

Table 60 Copolymers Made with SMAO Supported Catalysts Ex. Catalyst Catalyst Yield (g) GPC'H NMR VTEoS DSC No. from Amount (mg) Reaction [kgPE Mt Mw branching incorp. Tm& example Time (min) per g Ni)] (CH3 per (wt%) heat of fu- No. mole Ni [PDI] 100O CHZ) sion 329 325 203 88 20. 2 1. 2 102, 097 10. 7 1. 29 128. 7 °C [11. 6] [29. 7] [4. 92] 159 J/g [4. 92] 159 J/ 330 326 229 132 8. 66 no 105, 831 11. 1 2. 07 128. 0 °C [11. 6] [12. 7] flow [4. 90] 147 J/g 331 328 234 96 2. 70 no 126, 083 10. 6 1. 53 129. 1 °C [11. 6] [4. 0] flow [5. 23] 140. 2 J/g

Examples 332-337 Preparation of Crystalline Copolymers of Ethylene and Vinylsilanes Using Various Cocatalvsts.

Materials and General Procedure B (C6F5) 3, [HNMe2Ph] [B (C6F5) 4] and Li [B (C6F5) 4] (Et20) xwere purchased from Boulder Scientific. AIMe (BHT) 2 was prepared by a literature method: Shreve, A. P.; Mulhaupt, R.; Fultz, W.; Calabrese, J.; Robbins, W. ; Ittel, S. D.

Organometallics 1988,7, 409. [AlMe2 (Et2O) 2] + [MeB (C6F5) zu was prepared by literature methods; (a) Klosin, J.; Roof, G. R.; Chen, E. Y. -X. ; Abboud, K. A.

Organometallics 2000, 19, 4684. (b) Klosin, J. PCT Int. Appl. WO 0011006 (Dow Chemical Co. ). Vinyl silane comonomers (Aldrich Sure/SealTM) were stored over activated 5A molecular sieves and passed through activity 1 basic alumina immediately before use. Cyclopentene (Aldrich, 99%) was purified by passing it through a column containing activated 5A molecular sieves, fol- lowed by a column of activated neutral alumina, followed by refluxing over so- dium for 16 hours, followed by a careful distillation under nitrogen.

All polymerizations were done in a 450 mL jacketed autoclave at 60°C and 4.14 MPa constant pressure of ethylene using B. The mixing speed was 1200 RPM. The reaction was stopped by cooling the autoclave rapidly to RT followed by venting the unreacted ethylene. DSC of polymers was done with two heats from-20°C to 175°C at 10°C/min with a controlled cooling of 10°C/min between the two heats. The Tm and heat of fusion were recorded for the second heat. Molecular weight was determined by GPC in 1,2, 4- trichlorobenzene at 135°C vs. polystyrene standards using an RI detector.

Vinylsilane incorporation and hydrocarbon branching were determined by in- tegration of the 1H NMR. Ml (g/10 min) was determined at 190°C with a 2.16 kg weight. Polymerization results including analyses are summarized in Table 61.

Example 332 In a dry box, stock solutions of Li [B (C6F5) 4] (Et2O) (n # 2. 5,0. 090 g in 3.0 mL of chlorobenzene), B (C6F5) 3 (0. 090 g in 3.0 mL of toluene) and B (0.0085 g in 1.0 mL of toluene) were prepared. Aliquots of the Li [B (C6F5) 4] (Et2O) (0.343 mL, 4 mole equiv./Ni) and B (C6F5) 3 (0.260 mL, 5

mole equiv. /Ni) were added to a mixture of toluene (283 mL) and VTEoS (15 mL). This solution was transferred from a rubber septum capped RB flask by cannula into the dry autoclave under a nitrogen purge. In a drybox, an aliquot of the Ni catalyst (0.236 mL, 3.08 yole) was dissolved in 2.0 mL of dry tolu- ene and loaded into a small metal catalyst addition tube fitted with valves.

The catalyst addition tube was attached to the autoclave using a positive ni- trogen purge while making the connection. The autoclave was purged with ethylene, and then heated to the reaction temperature and pressurized with ethylene. The polymerization was started by opening the lower valve of the catalyst addition tube allowing the Ni catalyst solution to flow into the reactor.

The reaction time was 94 min. Polymer workup: the polymer slurry was poured into 750 mL of anhydrous MeOH in a blender. After mixing for several minutes the mixture was filtered on a sintered glass fritted filter. The polymer was washed on the filter with three 50 mL portions of anhydrous diethyl ether, and the polymer was dried overnight in vacuo at room temperature. Yield : 27.9 g of white solid. 13C NMR branching analysis (per 1000 CH2) : Total branches (11.0), Me (7.7), Et (0. 9), Pr (0. 6), Bu (0. 6), 2Am (1.3). Fraction of (CH2) n groups between the Si and the copolymer backbone: n=0 (53.9%), n=1 (25.8%), n=2 (9.6%), n=3 (10.4%), n>4 (0.3%).

Example 333 Preinitiation of the Catalyst in the Presence of Cyclopentene.

In a dry box, stock solutions of Li [B (C6F5) 4] (Et2O) (n 2.5, 0.050 g in 5.0 mL of diethyl ether), MeAl (BHT) 2 (0.096 g in 12.0 mL of diethyl ether) and catalyst/cyclopentene (0.0111 g of B and 0.050 mL of cyclopentene in 5.36 mL of diethyl ether) were prepared. Aliquots of the Li [B (C6F5) 4] (Et2O) (1. 8 mL, 5.4 mole equiv. /Ni) and MeAl (BHT) 2 (1. 2 mL, 5.2 mole equiv./Ni) were added to a 300 mL RB flask and the ether was allowed to evaporate. A solution of 3. 8 mL VTEoS in 146 mL toluene was prepared in a graduated cylinder.

Twelve mL of this solution was added to the RB flask followed by 1.2 mL of the catalyst/cyclopentene stock solution (4. 0 plmole Ni). After mixing, the so- lution was allowed to stand for 5 min, and then the remainder of the tolu- eneNTEoS solution was added. This solution of preactivated catalyst and comonomer was transferred from a rubber septum capped round bottom flask

by cannula into the dry autoclave under a nitrogen purge. The autoclave was purged by three successive pressure/vent cycles to 0.35 MPa ethylene. The autoclave was then heated to 60°C and the ethylene pressure was adjusted to 4.14 MPa. The reaction time was 1.6 h, and the polymer was worked up ac- cording to Example 332 except that anhydrous MeOH was used for washing the polymer on the filter rather than diethyl ether. Yield : 13.1 g white solid.

Example 334.

Polymerization was initiated by addition of a solution of catalyst (3.1 pirole Ni) in 2.0 mL toluene to an autoclave containing [ (CH3) 2PhNH] + [B (C6F5) 4] (1. 0 mole equiv./Ni), VTEoS (3.8 mL), and toluene (146 mL) at the temperature and pressure used in Example 332. Reaction time was 1.5 h and the polymer workup was identical to example 333. Yield: 16.5 g white powder.

Example 335 Preinitiated Catalyst in the Absence of Olefin In a dry box a 300 mL round bottom flask was charged with toluene (12 mL), VTEoS (3.8 mL), B (4. 6 mole), and [AlMe2(Et2O)2]+[MeB(C6F5)3] (1. 0 mole equiv./Ni). After standing for 5 min, the activated catalyst solution was diluted with 138 mL of additional toluene. Transfer of the solution to the auto- clave, polymerization, and workup were carried out according to Example 333. Reaction time was 0.5 h. Yield : 16.4 g white powder.

Example 336.

The polymerization procedure was essentially identical to Example 12 using B (3.1 limole), cocatalysts Li [B (C6F5) 4] (Et2O) n (5 mole equiv./Ni) and B (C6F5) 3 (5 mole equiv./Ni), toluene (143 mL), and vinyldimethylethoxysilane (United Chem Tech. , 7.5 mL) in place of VTEoS. Reaction time was 1 h.

Yield : 10.8 g white powder.

Example 337 Polymerization in Cyclohexane In a drybox B (4.6 pirole) was dissolved in 2.0 mL of anhydrous cyclo- hexane and placed in a catalyst addition tube. The catalyst [ (CH3) 2PhNH] + [B (C6F5) zu (1. 0 mole equiv. /Ni) was dissolved in 0.5 mL of chlo- robenzene and added to a 300 mL RB flask containing 1.25 mL of VTMoS.

After mixing the solution was diluted with 146 mL of anhydrous cyclohexane.

The polymerization was carried out according to Example 332. Reaction time was 0.5 h and the polymer workup was identical to Example 333. Yield : 19.6 g white powder.

Table 61 High Crystallinitv Copolymers Ex. Cocatalysts Vinyl Yield Mw'H NMR vinyl DSC No. silane (kg PE MI branching silane Tm& (mole equiv./Ni) per g [PDI] (CH3 per incorp. heat of [vol%] Ni) 1000 CH2) (mole%) fusion 332 B (C6F5) 3 (5) VTEoS 155 2. 6 67, 100 10. 7 0. 44 118 OC Li [B (C6Fs) 43 (4) [5] [2. 29j 146 J/g 333 MeAl (BHT) z (5. 2) VTEoS 56 71, 300 10. 5 0. 21 120. 3 °C Li [B (C6Fs) 4] (5. 4) [2. 5] [1. 98] 142 J/g 334 [(CH3) 2PhNH] VTEoS 91 3. 2 70, 800 11. 4 0. 22 120. 5 °C [B (C6Fs) 4] (1) [2. 5] [2. 11] 145J/g 335 [(CH3) 2Al (OEt2) 2] VTEoS 61 0. 93 91, 900 10. 0 0. 19 123. 9 °C [MeB (C6Fs) 3] (1) [2. 5] [2. 37] 162 J/g 336 B (C6Fs) 3 (5) 59 3. 2 58, 100 13. 4 0. 26 120. 7 °C Li [B (CsFs) 4] (5) [5] [1. 77] 145 J/g 337 [(CH3) 2PhNH] VTMoS 73 2. 0 11. 5 0. 19 [B (C6Fs>] (1) [0. 83] * CH2=CHSiMe2 (OEt) Example 338 Copolvmerization of Ethylene with CF3(CF2)7CH2CH2Si(OMe)2(CH=CH2) A solution of B (3.85 pmole) in 2.0 mL of toluene was added to a 450 mL autoclave held at 80°C, 4.14 MPa ethylene containing a toluene (130 mL) solution of cocatalysts Li [B (C6F5) 41- (Et2O) (5 mole equiv./Ni) and B (C6F5) 3 (5 mole equiv./Ni), and comonomer CF3 (CF2) 7CH2CH2Si (OMe) 2 (CH=CH2) (15.0 g) using the procedure described in Example 332. There was an exotherm to 87°C for about 30 sec after the addition of catalyst before the temperature was brought under control. The pressure was maintained at 4. 14 MPa during the polymerization, and the reaction was stopped after 2 h by cooling the autoclave rapidly to RT and venting the excess ethylene. The polymer slurry was poured into 300 mL of anhydrous MeOH in a blender. After mixing for several minutes the mixture was filtered on a sintered glass fritted filter. The polymer was washed on the filter with three 50 mL portions of anhydrous methanol. The filtered polymer was flushed with dry nitrogen in a covered container to remove the excess MeOH and then dried overnight in vacuo at

RT. In order to ensure that all of the unreacted vinylsilane was removed, the polymer was Soxhlet extracted with anhydrous MeOH for 6 h and then redried as above. Reaction details and polymer characterization are summarized in Table 62.

Example 339 Copolymerization of ethylene with CF3(CF2)7CH2CH2Si(OMe)2(CH=CH2) In a dry box, 15 g of CF3 (CF2) 7CH2CH2Si (OMe) 2 (CH=CH2) was dis- solved in 140 mL of anhydrous toluene. A solution of Li [B (C6F5) 4] (Et20) (5 mole equiv. /Ni) and B (C6F5) 3 (5 mole equiv. /Ni) in 2 mL of chlorobenzene was added, followed by 270 ul of an aliquot of a chlorobenzene stock solution of catalyst H (1. 0 mg, 0.82 pmole). This mixture was transferred to a dry nitro- gen-filled 450 mL autoclave by canula, and the polymerization and workup were carried out at 80°C and 4.14 MPa ethylene according to the procedure of Example 333. The reaction time was 1 h. Reaction details and characteri- zation are summarized in Table 62.

Table 62 Copolymers of CF3 CF2)7CH2CH2Si(OMe)2(CH=CH2) Ex. Yield (g) GPC'H NMR vinyl DSC No. MI branching silane Tm & [kg PE Mw (CH3 per incorp. heat of fu- per Ni PDI 000 CHz) oo sion 252 208 2. 7 70, 500 10. 4 1. 46" 120. 6 OC [89] [2. 01] 137 J/g w 338 27. 9 38. 2 33, 800 26. 4 1. 86 109. 1 °C [123] [2. 28] 107 J/g 339 2. 73 68 105, 831 9. 1 0. 50 125. 5°C [57] [4. 90] 159J/g Example 252: VTEoS comonomer (no fluorine), reaction conditions 60 °C, 4.14 MPa ethylene Example 340 Surface Characterization of Polymers Polymer samples used to press films were treated with antioxidant by washing on a filter two times with a 2% solution of Irganox0 1010 in acetone, and then drying in vacuo overnight at RT. A film of the polymer was prepared by pressing between PTFE sheets in a Pasadena@ press at 140°C for 1 min at 69 MPa. The film was removed easily from the PTFE, and a piece of film

was cut and placed on a glass slide where it was heated to 140°C for 1 min so that the outer surface was annealed to air. The advancing contact angles of water, CH212, and hexadecane were measured on the annealed polymer films.

The water and CH212 contact angles were used to calculate the surface ten- sion of the films by the harmonic mean method ("Polymer and Interface Adhe- sion", Sougeng Wu, Marcel Dekker, Inc., 1982). The results are summarized in Table 63.

Table 63 Surface Measurements: Contact Angles and calculated surface tensions. Ex. vinyl silicon fluorine Hz0 CH212 surface hexadecane No. silane content content contact contact tension contact an- incorp. (wt. %) (wt. %) angle angle (dynes/gle (wt. % g o g o Cill 252 1. 46 0. 216 OA 101. 0 0. 8 55. 56 33. 6 12. 4 0. 7 338 1. 86 0. 093 1. 06 104. 2 0. 6 63. 0 1. 3 30. 1 19. 3 + 1. 2 339 0. 50 0. 025 0. 29 108. 1 1. 2 43. 9 1. 4 # 13. 6 0. 4 A control sample made with vinyl triethoxysilane comonomer # no solution was found to the harmonic mean calculation The surface energy of homopolyethylene ranges from 33.7 to 36.8 de- pending upon the amount of branching and the molecular weight ("Polymer Handbook, 3rd Edition", Edited by J. Brandup and E. H. Immergut, Wiley Inter- science, 1989, page VU414). Thus the vinyl triethoxysilane copolymer (Ex- ample 252) has a surface tension at the low end of the range for homopoly- ethylene. However, its nonzero hexadecane contact angle distinguishes it from homopolyethylene which is wetted by hexadecane (i. e. contact angle is 0). Hexadecane contact angles are particularly sensitive to any non- hydrocarbon content of a surface. The reduced surface tension of Example 338 and the nonzero hexadecane contact angles of Examples 338 and 339 are consistent with partially fluorinated surfaces that have lower surface ten- sion than homopolyethylene.

Example 341 Copolvmerization of ethylene and VTEoS The supported catalyst from Example 194 (250 mg, 15.0 smote Ni) was used for the copolymerization of ethylene and VTEoS (2.5 volume %) in cy-

clohexane at 60°C and 4.14 MPa ethylene pressure following the procedure of Example 21 with a reaction time of 194 min. Yield : 31.2 g uniform spherical white polymer particles (35.4 kg copolymer per g Ni). There was no detectable fouling of the metal autoclave surfaces. DSC (second heat, 10°C/min) : Tm = 121. 7°C, 137 J/g. GPC (135 °C, TCB, Ri detector, vs. polystyrene) : Mw = 115,800 ; PDI =2. 66. MI (g/10 minutes, 2160 kg, 190°C) : noflow. 1H NMR branching: 18.9 CH3 per 1000 CH2. Weight% VTEoS by 1H NMR integration: 0.45.

Examples 342-351 General Procedure for Ethylene Vinylsilane Copolymerizations In a nitrogen-purged drybox, a glass vial with a gas inlet was loaded with the specified amounts of cyclohexane, vinylsilane and DD. The vial was greased and capped. The vial was then loaded in a reactor inside the drybox.

The reactor was sealed, brought outside of the drybox, and placed under the desired ethylene pressure and shaken mechanically. After the stated reaction time, the ethylene pressure was released and the vial was removed from the reactor. The polymer was precipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution. The methanol solu- tion was then decanted off of the polymer and the polymer was then washed with more methanol. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR spectra were run without Cr (acac) 3. Conditions and results are given in Table 64. Table 65 gives the 13C NMR branching analysis for some of the polymer of these Examples, while Table 66 gives the spacing analysis"n"for the polymer also listed in Table 65.

Table 64 Copolymerization of Ethylene and Vinylsilane with DD for 16 h in Cy- clohexane (Total Volume Vinylsilane + Cyclohexane = 10 mL)

Ex. DD Vinyl Temp Yield Comon M. W. Sol. D Totaì mmol Silane °C g lncorp. Mea mL (Press, mol% a kPa) 342 0. 0025 VTEoS 30 0. 37 1. 6 Mw=19, 861 ; S 119. 6 1. 11 (690) Mn=7, 985 343 0. 0025 VTMoS 30 0. 63 1. 7 MW=7, 540 ; S 119. 5 0. 8 (690) 1. 7 (C) Mn=1, 93386. 8" (C) 344 0. 01 VTEoS 60 2. 20 0. 8 Mu=24, 120 ; S 118. 3 1. 11 (1380) Mn=9, 287 345 0. 005 VTEoS 60 0. 51 0. 9 MW=25, 390 ; S 122. 4 1. 11 (1380) Mn=11, 799 346 0. 0025 VTEoS 60 0. 16 0. 8 Mw=30, 059 ; S 122. 3 1. 11 (1380) Mn=13, 316 347 0. 0025 VTMoS 60 0. 07 0. 9--121. 6 0. 8 (1380) 348 0. 02 VTMoS 60 4. 11 2. 1 Mi 5, 765 ; S 113. 6 2 (1380) 1. 9 (13C Mn=1, 857 80. 0 d (13c) 349 0. 02 VTMoS 60 1. 55 4. 1 Mu=3, 320 ; S 103. 3 5 (1380) 3. 7 (C) Mn=1, 051 71 Oe (13C) 350 0. 02 VTMoS 60 0. 64 5. 9 Mw=2, 602 ; S 94. 8 10 (1380) 5. 8 (13C) Mn=989 61. 7 (C) 351 0. 02 VTMoSg 60 0. 79 1. 24g Mi 10, 393 ; S- 1 (1380) Mn=3, 704 Data obtained from 1 H NMR spectroscopy, unless indicated otherwise.'Sol. : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material.

P=Partially soluble, e. g. , some insoluble material present. c1B1 = 21.1% and 1B2 = 34. 5%. d1B1 = 20.98% and 1B2 = 1. 07%. e% 1B1 = 23.8% and % 1B2 = 34.85%. f1B1 = 18. 34% and 1B2 =1.77%. These are percentages of branch on branch structures, see WO 9623010 for an explanation of these symbols. 9EGPEA (1 mL) was present as a termonomer (8 mL cy- clohexane was used): 4.16% IC EGPEA incorporation and 1.06% EOC EGPEA incorpora- tion.

Table 65 Ex. Total Me Et Pr Bu Hex+ Am+ & Bu+ & Me & eoc eoc eoc 343 86.8 28.6 1. 8 2. 8 14. 1 32. 4 3. 8 53.6 348 80.0 26.9 0 2.8 13.9 33.4 38.9 5.0 349 71.0 22.5 0 3.5 11.7 26.9 39.0 45.1 350 61.7 22. 0 0 2. 3 16.1 23.7 38. 6 37. 4 Table 66 Ex. n=0 n=1 n=2 n=3 n=4+ % % % % % 343 Nda Trace 29.4 12.7 57.9 348 Nda 5.4 25.3 16.1 53.2 349 Nda Trace 29.8 15. 9 54. 3 350 Nda 3. 5% 17. 8% 17. 1% 61. 6%

aNd : Not determined; overlaps with other resonances.

Examples 352-354 General Procedure for 1-HexeneNTMoS Copolymerizations In a nitrogen-purged drybox, a glass vial was loaded with the specified amounts of 1-hexene, VTMoS and DD. The glass vial was capped and placed on a mechanical shaker inside of the drybox where it was shaken for -1 month. The vial was then removed from the drybox and the polymer was precipitated by the addition of MeOH (-15 mL). A small amount of triethyla- mine was added to the solution. The methanol solution was then decanted off of the polymer and the polymer was then dissolved in hexane. The polymer was the reprecipitated in methanol and the methanol/hexane solution was de- canted off of the polymer. The polymer was dissolved in hexane, reprecipi- tated in methanol, etc. once again. The polymer was dried under vacuum for several days. The polymer yield and characterization were then obtained.

13C NMR spectra were run without Cr (acac) 3. Conditions and results are given in Table 67. 13C NMR branching analyses are given in Table 68, and the value of"n", the spacing between the polymer chain branch point and the silicon atom is given in Table 69 Table 67 Copolymerization of 1-Hexene and VTMoS with Pd catalyst DD (Total Volume Vinylsilane + 1-Hexene = 10 mL)

Ex. VTMoS Yield Comon M. W. Sol.,, Total mL g Incorp. Mea mol% a 352 0. 2 2. 16 1. 4 MW=300989 S 109 4 1. 5 (13C) Mn=6, 858 107. 1 ("C)- 352 0. 5 2. 00 2. 8 MW= =18, 395 ; S 112. 0 2. 9 (C) Mn=5565 109. 0 (13C) 354 1 1. 69 5. 0 Mw=8, 670 ; S 104. 3 5. 1 (13C) Mn=3, 328 99. 6 (C) Data obtained from 1 H NMR spectroscopy, unless indicated otherwise. DSol. : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material.

P=Partialiy soluble, e. g. , some insoluble material present.

Table 68 Ex. Total Me Et Pr Bu Hex+ Am+ & Bu+ & Me & eoc eoc eoc 352 107. 1 72. 9 1. 0 1.2 11. 7 18. 5 18. 9 32.1 353 109.0 73.4 1.9 1.3 12.1 17.1 22.7 32. 3 354 99. 6 67. 8 1. 1 1.4 21.3 15.2 22.7 29.2 Table 69 Ex. n=0 n=1 n=2 n=3 n=4+ % % % % % 352 Nd Nd Nd 43.1 56.9 353 Nd Nd Nd 16.4 83.6 354 Nd Nd 23.8 14.1 62.1 aNd : Not detected/trace Example 355 Synthesis of Silica Supported Catalyst A 1.50 g sample of dried SylopolX 948 (calcined at 500°C under nitro- gen) was added to a vial with 10 g of toluene, 78 mg of B (C6F5) 3 and 19 mg of NMe2Ph. The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 30 min. The isolated solid was added to a vial with 10 g of toluene and a sample of B (0.075 mmol, 49 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times

with pentane (10 mL) and dried under vacuum for 30 min. Yield : 1.566 g of dark solid.

Example 356 Synthesis of Silica Supported Catalyst A 1.50 g sample of dried SylopolX 948 (calcined at 500°C under nitro- gen) was added to a vial with 10 g of toluene, 78 mg of B (C6F5) 3 and 19 mg of NMe2Ph. The sample vial was capped and mechanically shaken for 1 h. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 30 min. The isolated solid was added to a vial with 10 g of toluene and a sample of RR (0.075 mmol, 53 mg). The sample vial was capped and mechanically shaken for 30 min. The slurry was filtered and rinsed 3 times with toluene (10 mL) and rinsed 3 times with pentane (10 mL) and dried under vacuum for 30 minutes. Yield : 1. 566 g of dark solid.

Example 357 Copolymerization of Ethvlene and VTMoS The supported catalyst from Example 355 (200 mg, 9. 571mole Ni) was used for the copolymerization of ethylene and VTMoS (5.0 volume %) in cy- clohexane (150 mL total volume) at 75°C and 4.14 MPa ethylene pressure following the procedure of Example 172. Yield : 10.9 g white powder. Details and polymer characterization are summarized in Table 70.

Example 358 Copolymerization of Ethylene and VTEoS The supported catalyst from Example 356 (132 mg, 6.3 pmole Ni) was used for the copolymerization of ethylene and VTEoS (5. 0 volume %) in cy- clohexane (150 mL total volume) at 75°C and 4.14 MPa ethylene pressure following the procedure of Example 172. Yield : 3.44 g white powder. Details and polymer characterization are summarized in Table 70.

The particle size distribution of the powder isolated in Examples 357 and 358 were measured on a Beckman Coulter LS230 (a laser diffraction in- strument) with size range of 0.04 to 2000 microns. The large particle size (peak of distribution about 300 jar and narrow distribution of Example 358 is consistent with polymer formation occurring exclusively on the supported

catalyst. The bimodal distribution of Example 357 (peaks at about 11 and 250 cm suggests that part of the polymer was made on the supported catalyst, and part of the polymer was made in solution from catalyst that leached off of the support. This interpretation is supported by the bimodal melting behavior observed in the DSC of Example 357. Optical microscopy and SEM of Ex- ample 357 show a mixture of large relatively uniform shaped particles along with smaller irregular shaped particles that appear to be aggregates of even smaller particles. Optical microscopy and SEM of Example 358 show only large relatively uniform shaped particles consistent with the replication of morphology of the starting Sylopol@ 948 support.

Example 359 Copolymerization of Ethylene and VTEoS A large sample of catalyst was prepared by the method described in Example 356. In a dry box, this catalyst (2.50 g, 0.125 mmol) was loaded into a 0.95 cm by 30.5 cm stainless steel blow case and connected to a 150 mL blow case containing anhydrous toluene with a ball valve between the two blow cases and with valves on both ends. A separate 500 mL blow case was charged with 200 mL of VTEoS (8.0 volume% of total reaction) that had been sparged with nitrogen, dried over activated 5A molecular sieves, and passed through a column of activity 1 neutral alumina (10.2 cm by 5.1 cm bed). A 3.8 I autoclave was heated to 140 °C and purged with dry nitrogen for 4 h. The autoclave was cooled to 60°C under nitrogen. The autoclave was charged with 2. 5 1 of anhydrous pentane under nitrogen purge. The two blow cases were attached to the autoclave while purging the valves with nitrogen. The autoclave was purged with ethylene and heated to 75°C. The VTEoS was pushed into the autoclave with 3.62 MPa ethylene pressure. The VTEoS/pentane mixture was stirred at 600 rpm under 3.62 MPa ethylene pressure to saturate the solution with ethylene. The blow case containing toluene was pressured to 4.14 MPa ethylene, then the valve was opened between the toluene and catalyst blow case, and then the entire contents of both blow cases were pressured into the reactor. After the pressure in the autoclave equalized to 4.14 MPa, the catalyst blow case was isolated from the autoclave, and ethylene was fed to the autoclave via a dip tube to maintain

the ethylene pressure at 4.14 MPa. After 5.5 h reaction time the autoclave was vented and cooled. The polymer was filtered on a large fritted glass filter by vacuum suction, and then washed twice on the filter with 1 liter of anhy- drous ether. The polymer was dried in vacuo with a nitrogen sweep at room temperature for 18 hours. Yield : 268 g of uniform free-flowing white power.

There was no evidence of fouling of the metal surfaces of the autoclave. Re- action parameters and polymer characterization are summarized in Table 70.

DSC measurements were done by the ASTM method (2160 g, 190°C) with a six min preheat before the first cut was taken. In order to judge the melt sta- bility of the polymer, the sample was left in the apparatus for an additional 15 min at 190°C after the first cut and then another cut was taken. There was no change in the MI after this hold time thus establishing that the polymer has good melt stability toward crosslinking at these conditions.

Table 70 Ex. Catalyst Yield (g) Mi GPC'H NMR vinyl DSC No. Amount [kg PE Mw branching silane Tm& No. Amount [kg PE Mw (mg) per g Ni] (CH3 per incorp. heat of fu- mole Ni [PDì] 1000 CHs) (wt%) sion 357 200 10. 9 5. 9 73, 200 14. 5 2. 27 128. 7 °C [9. 08] [19. 4] [3. 69] 113. 4 °C (shoulder) 139 J/g 358 132 3. 44 1. 1 100, 000 8. 7 0. 59 129. 4 °C [6. 3] [9. 3] [3. 79] 157 J/g 359 2500 267 0. 6 8. 9 1. 34 [125] [36. 4] Examples 360-361 ENinylsilane Copolymerizations Producing Copolymers with Silyl-Substituted Vinylidene End Groups In a nitrogen-purged drybox, a glass vial with a gas inlet was loaded with the specified amounts of B (C6F5) 3, Ni cmpd (as a solution in 0.2 to 0.5 mL Et2O), cyclohexane and VTMoS, with the total volume of cyclohexane and VTMoS being 10 ml. The vial was greased and capped. The vial was then loaded into a reactor inside the drybox. The reactor was then sealed, brought outside of the drybox, placed under the desired ethylene pressure, heated to 60°C, and shaken mechanically. After 16-18 h, the ethylene pressure was released and the vial was removed from the reactor. The polymer was pre-

cipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution. The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR spectra were run without Cr (acac) 3. Conditions and results are reported in Tables 71-74. In Table 75 the 13C NMR of the product of Example 361 is given. In Table 75 the"Designation"means the particular carbon atom shown in Figure 3, which the 13C NMR of the product of Example 361. Other designations shown in Table 75 are explained above in the section on NMR measurements.

Table 71 Ex. Cmpd B (C6F5) 3 VTMoS Press Yield VTMoS M. W. Sol."Total mmol mg mL MPa g Incorpa Mea Mol% 3C0 M 0 1 2.'I 1. 43 4. 5 MW=37, 541 ; P 33 0 0. 005 4. 1 ! C&EB Mn=1, 051 0. 4EG 361 J 2. 6 10 4. 1 7. 43 10. 7 Mw=657 ; S 17. 7 0. 002 7. 87IC&EB Mn=285 13C 2. 87 EG NMR : '3C NMR : 21. 9 14. 0 11. 2 IC&EB 2. 8 EG aData obtained from 1H NMR unless specified otherwise. Sot. : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g. , some insoluble material present.

Table 72 3C NMR Branching Analysis for Example 361 Total Me Me Et Pr Bu Hex+ & eoc Am+ & eoc Bu+ & eoc 21. 9 3. 1 2. 6 0 0 8. 1 15. 2 16. 2 Table 73 Spacing (n) between Si and the Copolymer Backbone for Example 361 n=0, % n=1, % n=2, % n=3, % n=4+, % 25. 3 7. 8 Nd Trace 66. 9 °Nd : Not detected.

Table 74 1H NMR Analysis of the Distribution of Olefins End Groupsa Ex. R-CH=CH % R-CH=CH-R', % R-CH=CH-Si (OMe) 3 % R [(MeO)3Si]-C=CH2 % 360 38.1 18.7 14. 3 28. 9 361 11.8 15.8 52. 4 20. 0

aR, Polymer chain.

Table 75 13C NMR Spectrum of the Product of Example 361 number PPM intensity Designation number PPM intensity Designation 1 155. 338 4. 1 74 32.932 35. 5 3 153.787 39.3 V 75 32.622 6.3 5 144.089 12.4 76 31.897 30.6 3B6+ 8 140. 415 5. 1 77 31.785 6. 8 10 139.754 7. 1 78 30.058 35.2 (CH2)x 11 139.070 12.3 F 79 29.707 1534.7 (CH2) x 12 137. 265 5. 4 80 29.486 105.1 (CH2)x 13 136.678 6. 4 81 29.292 74. 1 (CH2)x 136-127 solvent 82 29.180 55.5 (CH2)x 51 125.115 4. 5 83 28.974 30. 9 (CH2)x 54 123.549 5.4 C 84 28.907 22.3 (CH2)x 57 118.937 35.3 U 85 28.530 38.8 (CH2) x 59 117.667 4. 1 86 27.143 8.5 60 114.157 12.2 E 87 27.027 5.9 63 50.617 6.6 OMe 88 23.141 11.3 MSBo 64 50.228 70.9 OMe 89 22.685 37 2SBs+ 65 50.146 72.9 OMe 90 22. 561 35.4 2Bs+ 66 49.989 239.2 OMe 91 19. 654 4 B 67 49.780 16. 4 OMe 92 16.668 4.6 X 68 37.267 7. 2 93 15.277 4.7 1 SB 69 36.509 34.1 Y 94 13.947 6. 3 Z 70 36.101 15. 5 95 13.719 34.6 1 B4+ 73 33.620 11. 196 9. 526 33.1 1SB4+

Examples 362-365 Ethylene Copolymerization with Various Vinylsilanes In a nitrogen-purged drybox, a glass vial with a gas inlet was loaded with the specified amounts of B (C6F5) 3, LiB (C6F5) 42.5Et2O, Ni cmpd (as a so- lution in 0.2 to 0.4 mL Et2O), solvent and vinylsilane (total volume of vinylsilane and solvent was 10 ml). The vial was greased and capped. The vial was then loaded in a reactor inside the drybox. The reactor was then sealed, brought outside of the drybox, placed under the desired ethylene pressure and shaken mechanically. After 16-18 h, the ethylene pressure was released

and the vial was removed from the reactor. The polymer was precipitated by the addition of MeOH (-20 mL). A small amount of triethylamine was added to the solution. The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR spectra were run without Cr (acac) 3. Conditions and re- sults are shown in Table 76. Further details of the properties of the polymer of Example 363 are shown in Table 77 and 78.

Table 76 Ethylene Copolymerization with H2C=CH-Si(OR)3 (R=i-Pr, Ph, SiMe3 and 1, 3-Divinyltetramethyldisoloxane (DV;H2C=CHSi(Me)2OSi(Me)2CH=CH2) Ex. Cmpd B (C6F5) 3 VS Temp Yield VS M. W." Total mmol mg mL °C 9 Incorp. a Mea (LiB (C6F5) 4 (Solvent) (Press mol% mg) MPa) 362 X 102. 4 R=i-Pr 60 (4. 1) 0. 034 0. 7 MW-38, 95OR 12. 3 0. 002 (0) 1. 41 Mn=13, 497 (p-Xylene) 363 X 102. 4 R = Ph 60 11. 0 1. 1 Mw=19, 301 ; 17. 7 0. 002 (0) 1. 56 (4. 1) 13c Mn=5, 409 C (p-Xylene) NMR : NMR : NMR : 1. 72 22. 3 364 B 5. 2 R=SiMe3 105 3. 46 0. 2 M, =26, 059 ; 58. 6 0. 001 (0. 87) 1. 95 (2. 8) Mn=7, 499 (Toluene) 365 W 5. 1 DV 60 0. 93 0. 29C Mn=5 155d 5 7 0. 005 (4. 4) 0. 5 (2. 8) (Cyclo- hexane) Data obtained from'H NMR unless specified otherwise.'Data obtained from GPC unless specified otherwise. According to the 1H NMR spectrum, one of the vinyl groups of DV is incorporated in the polymer and the other remains unreacted. dObtained by end group analy- sis in the 1H NMR spectrum.

Table 77 3C NMR Branching Analysis for Example 363 Total Me Me Et Pr Bu Hex+ & eoc Am+ & eoc Bu+ & eoc - I- Table 78 Spacing (n) between Si and the Copolymer Backbone for Example 363 n=0 n=1 n=2 n=3 n=4+ % % % % % 33.33 Nd 26. 67 20. 0 20.0

aNd : Not determined.

Examples 366-373 E/1-Octene/VTMoS Copolymerizations In a nitrogen-purged drybox, a glass vial with a gas inlet was loaded with the specified amounts of B (C6F5) 3 (10.2 mg), and LiB (C6F5) 42. 5Et20 (3.4 mg), followed by the addition of cyclohexane, VTMoS (total volume of cyclo- hexane and VTMoS was 10 ml,) 1-octene, and the Ni cmpd (0.04 mmol) dis- solved in 0.2 mL of Et20. The vial was greased and capped. The vial was then loaded in a reactor inside the drybox. The reactor was then sealed, brought outside of the drybox, placed under the desired ethylene pressure, heated to 120°C, and shaken mechanically. After 3 h, the ethylene pressure was released and the vial was removed from the reactor. The polymer was precipitated by the addition of MeOH (-20 mL). A small amount of triethyl- mine was added to the solution. The polymer was then collected on a frit and rinsed with MeOH. The polymer was transferred to a pre-weighed vial and dried under vacuum for several days. The polymer yield and characterization were then obtained. 13C NMR spectra were run without Cr (acac) 3. Conditions and results are shown in Table 79.

Table 79 E/1-OcteneNTMoS Copolymerizations

Ex. Cmpd VTMoS Press Yield VTMoS M. W. Sol. Total mL psi 9 Incorp. a Mea (1-Octene mol% mL) 366 LL 0. 5 500 1. 72 0. 9 MW=92s415 ; S 107. 8 (0. 5) Mn=18, 113 367 MM 0. 5 500 1. 72 2. 1 Mu=47, 279 ; S 97. 9 (0. 5) Mn=11, 064 368 KK 0. 5 500 1. 32 0. 6 Mw=239, 786 ; P 111. 0 (0. 5) Mn=55, 675 369 KK 1 500 1. 01 1. 1 Mw=176, 166 ; P 103. 1 (1) Mn=12, 969 370 LL 0. 5 700 2. 28 0. 8 Mw=131, 187 ; P 100. 3 (0. 5) Mn=16, 932 371 MM 0. 5 700 2. 44 1. 2 MW=150, 862 ; S 87. 4 (0. 5) Mn=9, 771 372 KK 0. 5 700 1. 56 0. 6 Mw=291, 890 ; P 94. 5 (0. 5) Mn=65, 006 373 KK 1 700 1. 57 1. 7 MW-320, 028 ; P 113. 3 (1) Mn=61, 588 aData obtained from'H NMR unless specified otherwise. Soi. : Solubility of copolymer in TCB at 135 °C. S = Totally soluble or only a slight amount of insoluble material. P=Partially soluble, e. g. , some insoluble material present.