BACKGROUND OF THE INVENTION An accepted literature teaching is that wear rates of materials, including polymers, can be correlated to mechanical properties of such materials. Mechanical properties include hardness, tensile break strength and elongation to break.

See, e.g., J. R Lancaster, "Relationship Between the Wear of Polymers and Their Mechanical Properties", Proceedings of the Institution of Mechanical Engineers 1968-69, Volume 183, Part 3P, pages 98-106.

Anne E. Bovari and Sherry B. Glenn, in "Selecting Materials for Wear Resistance", Plastics Engineering, December 1995, pages 31-33, make several observations regarding abrasion at page 32. "Abrasion occurs in contacts in which one surface is considerably harder than the other, e.g., sandpaper on wood".

They note that, "in such a situation, the asperities of the harder surface penetrate the softer surface, and, as a result of relative motion, material is displaced from the softer body". They suggest that wear particle generation should be low and abrasion resistance high when a material has a high hardness or resistance to penetration by the asperities.

The American Society for Testing and Materials (ASTM) standard test method for abrasion resistance is ASTM D 1630-83.

The test method is particularly suitable for determining resistance to abrasion of vulcanized rubber or other compounds, used for footwear soles and heels. The method employs a National Bureau of Standards (NBS) abrasion machine.

Mike Wilson, in "Slip Resistance Performance of Soling Materials", SATRA Bulletin, May 1996, pages 77-79, a publication produced by SATRA Footwear Technology Centre, suggests, at page 78, that a minimum coefficient of friction (COF) for footwear soles and heels on dry and wet quarry tile is 0.3. He also suggests, at page 79, that footwear for sports and industrial applications may be more demanding in terms of slip resistance and require a COF of at least 0.4, sometimes at least 0.6.

In order to attain acceptable product life for footwear soles and heels, an improvement in abrasion resistance appears to be desirable. By following the teachings of Lancaster and Bovari et al., one approach to improving abrasion resistance is to increase hardness in order to minimize penetration by asperities. This approach, however, has its limits. At some point, the hardness is so high that consumers will not accept use of the material in footwear soles and heels because they are uncomfortable.

Footwear designers also have hardness limitations because increasingly hard materials have fewer processing options.

A perceived need, particularly for footwear end use applications such as soles and heels, exists for improving abrasion resistance of a material without increasing its hardness to a level that renders it unacceptable from a consumer or designer perspective.

SUMMARY OF THE INVENTION An aspect of the invention is a nonporous, grafted and crosslinked elastomer composition comprising at least one ethylene/alpha-olefin (EAO) interpolymer elastomer that has a hardness (Shore A) < 85 and, optionally, at least one crystalline olefin polymer, the elastomer being grafted with a silane moiety

that promotes crosslinking of the grafted elastomer in the presence of moisture and then crosslinked following exposure to moisture, the grafted and crosslinked elastomer composition having a hardness (Shore A) < 85 and an abrasion resistance (ASTM D 1630-83, NBS Abrader) that is greater than that of either a crosslinkable composition that is the elastomer composition prior to grafting and crosslinking or a like composition prepared using an ungrafted version of the same ethylene/alpha-olefin inter- polymer elastomer. The abrasion resistance of the grafted and crosslinked elastomer composition is desirably at least 25 percent (%) greater, preferably at least 50% greater, than that of either the elastomer composition prior to grafting and crosslinking or the like composition.

A second aspect of the invention is a crosslinkable elastomer composition comprising at least one grafted EAO interpolymer elastomer that has a hardness (Shore A) < 85 and, optionally, at least one crystalline olefin polymer, the elastomer being grafted with a silane moiety that promotes crosslinking of the grafted elastomer in the presence of moisture, the crosslinkable composition having an abrasion resistance and, following exposure to moisture, yielding a grafted, crosslinked elastomer composition that has an abrasion resistance, the abrasion resistance of the crosslinked composition being greater than the abrasion resistance of the crosslinkable composition, desirably at least (2) 25% greater, preferably 2 50% greater.

DESCRIPTION OF PREFERRED EMBODIMENTS Unless otherwise stated herein, all ranges include both end points.

"Ethylene polymers" means an EAO copolymer or a diene modified EAO copolymer. Illustrative polymers include ethylene/propylene (EP) copolymers, ethylene/octene (EO) copolymers, ethylene/butylene (EB) copolymers and ethylene/ propylene/diene (EPDM) interpolymers. More specific examples include ultra low linear density polyethylene (ULDPE) (e.g., Attanew made by The Dow Chemical Company), homogeneously

branched, linear ethylenela-olefin copolymers (e.g. Tafmer by Mitsui PetroChemicals Company Limited and Exacts by Exxon Chemical Company), homogeneously branched, substantially linear ethylenela-olefin polymers (e.g. the AffinityTM polymers available from The Dow Chemical Company and Engages polymers available from DuPont Dow Elastomers L.L.C.), and high pressure, free radical polymerized ethylene copolymers such as ethylene/vinyl acetate (EVA) polymers (e.g., the Elvax polymers manufactured by E. I. Du Pont de Nemours & Co.). The more preferred olefinic polymers are the homogeneously branched linear and substantially linear ethylene copolymers with a density (measured in accordance with ASTM D-792) from 0.85 to 0.92 grams per cubic centimeter (g/cm3), especially from 0.85 to 0.90 g/cm3 and a melt index or MI (measured in accordance with ASTM D-1238 (190°C/2.16) from 0.01 to 500, preferably from 0.05 to 30 grams per ten minutes (g/ 10 min.). The substantially linear ethylene copolymers and the various functionalized ethylene copolymers such as EVA (containing from 0.5 to 50 wt % units derived from vinyl acetate) are especially preferred. EVA polymers that have a MI (ASTM D-1238 (190"C /2.16) of from 0.01 to 500, preferably from 0.05 to 150 g/10 minutes are very useful in the present invention.

"Substantially linear" means that a polymer has a backbone substituted with from 0.01 to 3 long-chain branches per 1000 carbons in the backbone.

"Long-chain branching" or "LCB " means a chain length of 2 6 carbon atoms. Above this length, carbon 13 nuclear magnetic resonance (C13 NMR) spectroscopy cannot distinguish or determine an actual number of carbon atoms in the chain. In some instances, a chain length can be as long as the polymer backbone to which it is attached. For ethylene/alpha-olefin copolymers, the long chain branch is longer than the short chain branch that results from the incorporation of the alpha-olefin(s) into the polymer backbone.

"Interpolymer" refers to a polymer having polymerized therein at least two monomers. It includes, for example,

copolymers, terpolymers and tetrapolymers. It particularly includes a polymer prepared by polymerizing ethylene with at least one comonomer, typically an a-olefin of 3 to 20 carbon atoms (C3- C20). Illustrative a-olefins include propylene, l-butene, l-hexene, 4-methyl-1-pentene, l-heptene, l-octene and styrene. The a-olefin is desirably a C3-C10 defin. Preferred copolymers include EP and EO copolymers. Illustrative terpolymers include an ethylene/propylene/octene terpolymer as well as terpolymers of ethylene, a C3-C20 a-olefin and a diene such as dicyclopentadiene, 1,4-hexadiene, 1,3-pentadiene (piperylene) or 5-ethylidene-2- norbornene (ENB). The terpolymers are also known as EPDM terpolymers where the a-olefin is propylene or generically as EAODM terpolymers.

The substantially linear ethylene a-olefin interpolymers ("SLEPs" or "substantially linear ethylene polymers") are characterized by narrow molecular weight distribution (MWD) and narrow short chain branching distribution (SCBD) and may be prepared as described in United States Patent (USP) 5,272,236 and 5,278,272, relevant portions of both being incorporated herein by reference. The SLEPs exhibit outstanding physical properties by virtue of their narrow MWD and narrow SCBD coupled with LCB.

The presence of LCB in these olefinic polymers allows for easier processing (faster mixing, faster processing rates) and allows for more efficient free radical crosslinking. USP 5,272,236 (column 5, line 67 through column 6, line 28) describes SLEP production via a continuous controlled polymerization process using at least one reactor, but allows for multiple reactors, at a polymerization temperature and pressure sufficient to produce a SLEP having desired properties. Polymerization preferably occurs via a solution polymerization process at a temperature of from 20"C to 250"C, using constrained geometry catalyst technology.

Suitable constrained geometry catalysts are disclosed at column 6, line 29 through column 13, line 50 of USP 5,272,236.

These catalysts may be described as comprising a metal coordination complex that comprises a metal of groups 3-10 or the Lanthanide series of the Periodic Table of the Elements and a

delocalized pi-bonded moiety substituted with a constrain-inducing moiety. The complex has a constrained geometry about the metal atom such that the angle at the metal between the centroid of the delocalized, substituted pi-bonded moiety and the center of at least one remaining substituent is less than such angle in a similar complex containing a similar pi-bonded moiety lacking in such constrain-inducing substituent. If such complexes comprise more than one delocalized, substituted pi-bonded moiety, only one such moiety for each metal atom of the complex is a cyclic, delocalized, substituted pi-bonded moiety. The catalyst further comprises an activating co-catalyst such as tris(pentafluoro-phenyl)borane.

Specific catalyst complexes are discussed in USP 5,272,236 at column 6, line 57 through column 8, line 58 and in USP 5,278,272 at column 7, line 48 through column 9, line 37. USP 5,272,236, at column 8, lines 34-49, and USP 5,278,272, at column 9, lines 21- 37, disclose as specific catalyst complexes: (tert-butylamido) (tetramethyl-115-cyclopentadienyl)- 1 1,2-ethanediylzirconium dichloride, (tert-butylamido)(tetramethyl-q5-cyclopentadienyl)- 1,2-ethanediyltitanium dichloride, (methylamido)(tetramethyl-rl5- cyclop entadienyl) -1,2 - ethanediylzirconium dichloride, (methylamido) (tetramethyl-rl 5-cyclopentadienyl) -1,2-ethane- diyltitanium dichloride, (ethylamido) (tetramethyl-715-cyclo- pentadienyl)-methylenetitanium dichloro, (tert-butylamido)- dibenzyl(tetramethyl-Tl5-cyclopentadienyl)silanezirconium dibenzyl, (benzylamido)dimethyl(tetramethyl-rl5-cyclopentadienyl) -silane- titanium dichloride, (phenylphosphido)dimethyl(tetramethyl-#5- cyclopentadienyl)silanezirconium dibenzyl, and (tert-butylamido)- <BR> <BR> <BR> dimethyl(tetramethyl-17 5 - cyclopentadienyl) silanetitanium dimethyl.

The teachings regarding the catalyst complexes in general and these specific complexes are incorporated by reference.

A SLEP is characterized by a narrow MWD and, if an interpolymer, by a narrow comonomer distribution. A SLEP is also characterized by a low residuals content, specifically in terms of catalyst residue, unreacted comonomers and low molecular weight (MW) oligomers generated during polymerization. A SLEP is further characterized by a controlled molecular architecture that

provides good processability even though the MWD is narrow relative to conventional olefin polymers.

A preferred SLEP has a number of distinct characteristics, one of which is a comonomer content that is between 20 and 80 weight percent (wt%), more preferably between 30 and 70 wt%, ethylene, with the balance comprising one or more comonomers. SLEP comonomer content can be measured using infrared (IR) spectroscopy according to ASTM D-2238 Method B or ASTM D-3900. Comonomer content can also be determined by C13 NMR Spectroscopy.

Additional distinct SLEP characteristics include 12 and melt flow ratio (MFR or 110/12). The interpolymers desirably have an I2 (ASTM D-1238, condition 1900C/2. 16 kilograms (kg) (formerly condition E)), of 0.01-500 g/10 min, more preferably from 0.05-150 g/10 min. The SLEP also has a I10/I2 (ASTM D-1238) 2 5.63, preferably 6.5-15, more preferably 7- 10. For a SLEP, the Ilo/I2 ratio serves as an indication of the degree of LCB such that a larger Ilo/I2 ratio equates to a higher degree of LCB in the polymer.

A further distinct characteristic of a SLEP is MWD (Mw/Mn or "polydispersity index"), as measured by gel permeation chromatography (GPC). Mw/Mn is defined by the equation: Mw/Mn < (110/12) - 4.63 The MWD is desirably > 0 and < 5, especially 1.5- 3.5, and preferably 1.7- 3.

A homogeneously branched SLEP surprisingly has a MFR that is essentially independent of its MWD, This contrasts markedly with conventional linear homogeneously branched and linear heterogeneously branched ethylene copolymers where the MWD must be increased to increase the MFR.

A SLEP may be still further characterized as having a critical shear rate at onset of surface melt fracture (OSMF) of at least 50 % greater than the critical shear rate at the OSMF of a linear olefin polymer that has a like 12 and Mw/Mn.

SLEPs that meet the aforementioned criteria are suitably produced via constrained geometry catalysis by The Dow Chemical Company and DuPont Dow Elastomers L.L.C.

For many elastomeric applications, such as wire and cable insulation, weather-stripping, fibers, seals, gaskets, foams, footwear, flexible tubing, pipes, bellows and tapes, certain physical properties, such as tensile strength, compression set and increased end use temperature of articles manufactured from one or more polyolefins can be enhanced by introducing chemical linkages between molecular chains that constitute the polyolefin(s). As used herein, "crosslink(s)" refers to the presence of two or more chemical linkages between the same two molecular chains. Where only one chemical linkage exists between two molecular chains, that is referred to as a "branch point" or "branching". Crosslinks and branch points can be introduced between different molecular chains by any of a number of mechanisms. One mechanism involves grafting a chemically reactive compound to individual molecular chains or polymer backbones that constitute a bulk polymer in such a manner that the grafted compound on one chain may subsequently react with a similar grafted compound on another chain to form the crosslink, branch point or both. Silane crosslinking exemplifies this mechanism.

Any silane, or a mixture of such silanes, that will effectively graft to components of the elastomer compositions of the present invention, especially the elastomer phase, can be used as the silane moiety in the practice of this invention. Suitable silanes include those of the general formula: in which R' is a hydrogen atom or methyl group; x and y are 0 or 1 with the proviso that when x is 1, y is 1; n is an integer from 1 to 12 inclusive, preferably 1 to 4, and each R independently is a hydrolysable organic group such as a C1-12 alkoxy group (e.g.

methoxy, ethoxy, butoxy), an aryloxy group (e.g. phenoxy), an aralkoxy group (e.g. benæyloxy), a Cl l2 aliphatic acyloxy group (e.g. formyloxy, acetyloxy, propanoyloxy), amino or substituted amino groups (alkylamine, arylamino), or a lower alkyl (C1-6) group, with the proviso that not more than two of the three R groups is an alkyl (e.g., vinyl dimethyl methoxy silane). The use of "C" with a subscript range denotes the number of carbon atoms in, for example, a lower alkyl group. Silanes useful in curing silicones which have ketoximino hydrolysable groups, such as vinyl tris(methylethylketoamino) silane, are also suitable. Useful silanes include unsaturated silanes that comprise an ethylenically unsaturated hydrocarboxyl group, such as a vinyl, ally, isopropyl, butyl, cyclohexenyl or gamma-(meth)acryloxy allyl group, and a hydrolysable group, such as, for example, a hydrocarbyloxy, hydrocarbonyloxy, or hydrocarbylamino group. Examples of hydrolysable groups include methoxy, ethoxy, formyloxy, acetoxy, proprionyloxy, and alkyl or arylamino group. Preferred silanes are the unsaturated alkoxy silanes which can be grafted onto the polymer. Vinyl trimethoxy silane, vinyl triethoxy silane, gamma- (meth)acryloxy propyl trimethoxy silane and mixtures of these silanes are the preferred silanes for use in establishing crosslinks.

The amount of silane used in the practice of this invention can vary widely depending upon the nature of the elastomer phase components, the silane, the processing conditions, the grafting efficiency, the ultimate application, and similar factors, but typically 2 0.1, preferably 2 0.3, more preferably > 0.4, part of silane per hundred parts of elastomer resin (phr) is used. Considerations of convenience and economy are usually the principal limitations on the maximum amount of silane used in the practice of this invention. Typically the maximum amount of silane does not exceed 3.5, preferably it does not exceed 2.5, more preferably it does not exceed 2.0, phr. As used in "phr", "resin" means the elastomer plus any other polymer(s) included with the elastomer during grafting. An amount of less than 0.1 wt% is undesirable because it does not result in enough branching, crosslinking or both to give enhanced morphological and

rheological properties. An amount in excess of 3.5 wt% is undesirable because the elastomeric domains or phase becomes crosslinked to a level that is too high, thereby resulting in a loss of impact properties.

The silane is grafted to the resin (elastomer plus any other polymer(s) included with the elastomer during grafting), by any conventional method, typically in the presence of a free radical initiator such as a peroxide or an azo compound, or by ionizing radiation. Organic initiators, especially peroxide initiators, are preferred. Examples of peroxide initiators include dicumyl peroxide, di-tert-butyl peroxide, t-butyl perbenzoate, benzoyl peroxide, cumene hydroperoxide, t-butyl perbenzoate, benzoyl peroxide, cumene hydroperoxide, t-butyl peroctoate, methyl ethyl ketone peroxide, 2,5-dimethyl-2,5-di(t-butyl peroxy)hexane, lauryl peroxide, and tert-butyl peracetate. A suitable azo compound is azobisisobutyl nitrite. The amount of initiator can vary, but it is typically present in an amount of> 0.04, preferably 2 0.06, phr.

Typically the amount of initiator does not exceed 0.15, preferably it does not exceed about 0.10 phr. The ratio of silane to initiator can also vary widely, but a typical silane:initiator ratio is between 10:1 and 30: 1, preferably between 18:1 and 24:1.

While any conventional method can be used to graft the silane to the resin, one preferred method is blending the two with the initiator in the first stage of a reactor extruder, such as a single screw or a twin screw extruder, preferably one with a length/diameter (L/D) ratio of 25: 1 or greater. The grafting conditions can vary, but the melt temperatures are typically 1600C- 280"C, preferably 1900C-2500C, depending upon the residence time and the half life of the initiator.

Cure is preferably accelerated with a catalyst, and any catalyst that will provide this function can be used in this invention. These catalysts generally include organic bases, carboxylic acids and organometallic compounds including organic titanates and complexes or carboxylates of lead, cobalt, iron, nickel, zinc and tin. Illustrative catalysts include dibutyl tin dilaurate, dioctyl tin maleate, dibutyl tin diacetate, dibutyl tin

dioctoate, stannous acetate, stannous octoate, lead naphthenate, zinc caprylate and cobalt naphthenate. Tin carboxylate, especially dibutyl tin dilaurate and dioctyl tin maleate, and titanium compounds, especially titanium 2-ethylhexoxide, are particularly effective for this invention. The catalyst is preferably dibutyl tin dilaurate. The catalyst (or mixture of catalysts) is present in a catalytic amount, typically between 0.005 and 0.3 phr, based on weight of elastomer. The crosslinks, branch points or both that result from the cure process can form between two elastomer molecules, two crystalline polyolefin polymer molecules, an elastomer molecule and a crystalline polyolefin polymer molecule, or any combination thereof provided the requisite elastomer and crystalline polymer molecules are present.

A crosslinking catalyst, while preferred, is not needed to effect crosslinking of a silane-grafted elastomer. Crosslinking can occur over time by leaving compositions or articles containing a silane-grafted elastomer in a moist or steam-filled atmosphere.

Where time is not critical and energy savings are desired, a simple moist environment without added heating will suffice.

Elastomer compositions of the present invention may be fabricated into parts, sheets or other form using any one of a number of conventional procedures. These procedures include, for example, injection molding, blow molding and extrusion, with injection molding being preferred. The compositions can also be formed, spun or drawn into films, fibers, multi-layer laminates or extruded sheets, or can be compounded with one or more organic or inorganic substances, on any machine suitable for such purposes. Fabrication may be conducted either before or after moisture curing, but is preferably conducted before moisture curing for ease of processing.

The crystalline olefin polymer is suitably selected from an EAO polymer having an ethylene content of more than 85 wt%, based on copolymer weight, high density polyethylene, and propylene/ethylene copolymers having an ethylene content of no more than 10 wt%, based on copolymer weight.

Suitable polypropylene resins include, for example, propylene homopolymer, propylene/ethylene random copolymers, propylene/ethylene block copolymers, propylene/butene random copolymers, and propylene/ethylene/butene terpolymers.

Preparation of polypropylene resins involves the use of Ziegler catalysts, which allows the stereoregular polymerization of propylene to form isotactic polypropylene. The catalyst used is typically a titanium trichloride in combination with aluminum diethylmonochloride, as further described in Cecchin, USP 4,177,160. The various types of polymerization processes used for the production of polypropylene include the slurry process, which is run at 50-90"C and 0.5-1.5 MPa (5-15 atm), and the gas-phase and liquid-monomer processes, in which extra care must be given to the removal of amorphous polymer. Ethylene may be added to the reaction to form a polypropylene with ethylene blocks.

Polypropylene resins may also be prepared by using any of a variety of metallocene, single site and constrained geometry catalysts together with their associated processes.

Polypropylene resins, when included as a component of nonporous, grafted and crosslinked elastomer compositions of the present invention, are included in an amount that falls within a range of 1- 50 parts by weight (pbw) per hundred pbw of elastomer.

The range is preferably 5-30 pbw. The polypropylene resins desirably have a melt flow rate (MFR), measured at 230"C and 2.16 kilograms (kg), of 0.5- 70 g/10 min.

Extender oils, such as paraffinic oils, aromatic oils naphthenic oils, mineral oils and liquid polybutene, can be used in nonporous, grafted and crosslinked elastomer compositions of the present invention. Naphthenic oils are preferred for ethylene/alpha-olefin copolymers and paraffinic oils are preferred for EPDM and EAODM polymers. Extender oils perform functions such as reducing composition viscosity and softening the compositions. They are optional components, but, when present, are typically used in amounts that fall within a range of 1-150 pbw per 100 pbw of polymers contained within the compositions of the present invention. The range is preferably 15-100 pbw.

A variety of additives may be advantageously used in the compositions of this invention for other purposes such as the following, any one or more of which may be used: antimicrobial agents such as organometallics, isothiazolones, organosulfurs and mercaptans; antioxidants such as phenolics, secondary amines, phophites and thioesters; antistatic agents such as quaternary ammonium compounds, amines, and ethoxylated, propoxylated or glycerol compounds; fillers and reinforcing agents such as glass, metal carbonates such as calcium carbonate, metal sulfates such as calcium sulfate, talc, clays, silicas, carbon blacks, graphite fibers and mixtures thereof; hydrolytic stabilizers; lubricants such as fatty acids, fatty alcohols, esters, fatty amides, metallic stearates, paraffinic and microcrystalline waxes, silicones and orthophosphoric acid esters; mold release agents such as fine- particle or powdered solids, soaps, waxes, silicones, polyglycols and complex esters such as trimethylolpropane tristearate or pentaerythritol tetrastearate; pigments, dyes and colorants; plasticizers such as esters of dibasic acids (or their anhydrides) with monohydric alcohols such as o-phthalates, adipates and benzoates; heat stabilizers such as organotin mercaptides, an octyl ester of thioglycolic acid and a barium or cadmium carboxylate; ultraviolet light stabilizers used as a hindered amine, an o- hydroxy-phenylbenzotriazole, a 2-hydroxy,4-alkoxyenzophenone, a salicylate, a cynoacrylate, a nickel chelate and a benzylidene malonate and oxalanilide. A preferred hindered phenolic antioxidant is Irganox TM 1076 antioxidant, available from Ciba- Geigy Corp. Such additives, if used, typically do not exceed 45 wt% of the total composition, and are advantageously 0.001- 20 wt%, preferably 0.01- 15 wt% and more preferably 0.1- 10 wt%, based on total composition weight.

Articles of manufacture that may be fabricated from the nonporous, grafted and crosslinked elastomer compositions of the present invention include, for example, those selected from the group consisting of gaskets, membranes, sheets, footwear sole components, footwear upper components, shaft bushings, and wear-control articles such as hinges and drawer slides. Skilled

artisans will readily appreciate other articles of manufacture that may be fabricated from the compositions of the present invention.

The nonporous, grafted and crosslinked elastomer compositions of the present invention, particularly when fabricated into footwear sole components, have a coefficient of friction (COF), measured in accordance with ASTM D-1894 using mason tile (dry and wet), of at least 0.3. The COF, measured with wet mason tile, is beneficially at least 0.4, desirably at least 0.45, preferably at least 0.5, more preferably at least 0.55. The COF, measured with dry mason tile, is beneficially at least 0.4, desirably at least 0.6, preferably at least 0.9, more preferably at least 1.0. The same COF values apply to the crosslinkable compositions of the present invention following crosslinking and fabrication.

The following examples illustrate but do not, either explicitly or by implication, limit the present invention. Unless otherwise stated, all parts and percentages are by weight, on a total weight basis.

EXAMPLES Four different ethylene/octene polymers or SLEPs are used in the examples. All are available from DuPont Dow Elastomers L.L.C. Polymer A is available as Engages EG8445.

Polymer B is available as Engages EG8448. Polymer C is an experimental polymer and Polymer D is available as Engages EG8200. Table I below lists the density in grams per cubic centimeter (g/cm3), MI, in g/10 min and percent (%) crystallinity for each of the polymers.

The crystallinity of a polymer is determined by differential scanning calorimetry (DSC) on a TA Instrument 2920 DSC equipped with a liquid nitrogen cooling accessory. Samples are prepared in the form of thin films and placed in aluminum pans. They are heated initially to 1800C and maintained at this temperature for four minutes. They are then cooled at 10°C per minute to -100°C before being reheated to 140"C at 10°C per minute. The total heat of fusion is obtained from the area under the melting curve. The percent crystallinity is determined by

dividing the total heat of fusion by the heat of fusion value for polyethylene (292 joules per gram (J/g)).

Table I - Polymer Description Polymer Density MI % Desig- (g/cm3) (g/10 Crystal- nation min) linity A 0.910 3.5 33 B 0.896 1.6 27 C 0.858 1.7 3 D 0.870 5.0 10 Grafting is accomplished by a procedure that starts with weighing 22.7 kilograms (kg) of dry polymer pellets into a plastic lined cardboard drum (50 gallon(gal) or 200 liter(l)) together with a pre-weighed solution of vinyl trimethoxy silane (VTMOS) and dicumyl peroxide (DCP) in a ratio of VTMOS:DCP of 18: 1. The VTMOS and DCP are commercially available from Aldrich Chemical. The amount of VTMOS added is 1.8 wt%, based upon polymer weight. The contents of the drum are tumble blended for one hour to allow uniform absorption onto and into the pellets.

The contents of the container are then starve-fed to a ZSK 30 millimeter (mm), Werner Pfleiderer, co-rotating, twin screw extruder equipped with a high shear mixing screw. By operating at the temperatures (in degrees centigrade ("C)) shown in Table II below and at a speed of 100 revolutions per minute (rpm), the extruder effectively melt mixes the container contents and grafts the silane to the elastomer. Using a double strand die and a die pressure of 300 pounds per square inch (psi) (2.07 megapascals (Mpa)), extrudate exits the extruder at a rate of 15 to 20 pounds (6.8-9.1 kilogram (kg)) per hour. The extrudate enters the water bath where it is quenched. The quenched extrudate is then dried with an air knife, pelletized and placed in a wax lined bag. Prior to being placed in the bag, the resulting pellets are purged with dry nitrogen.

If an extender oil, such as ShellflexX 371, a naphthenic oil commercially available from Shell Chemical Company, is needed in a composition, the container contents, now pelletized, are passed a second time through the extruder and oil is added into zone two of the extruder using a pump and injection nozzle. Extruder operating temperatures needed for oil incorporation are also shown in Table II. For oil incorporation, the extruder operates at a speed of 250 rpm to provide an output of 25 to 30 pounds (11.3 to 13.6 kg) per hour. Extruder output is then processed as outlined above for polymer that contains no extender oil.

Table II - Extruder Operating Conditions Apparatus First Second (Oil Zone (Grafting) Incorporation) Pass Pass Temperatures Temperatures (°C) ("c) 1 140 - 164 2 160 68 3 180 102 4 205 137 5 206 145 Die ~ 190 142 Water Bath 13 13 A cure catalyst master batch is prepared using 11.4 kg Polymer D (Table I) and sufficient dibutyl tin dilaurate (DBTDL) (Aldrich Chemical) crosslinking catalyst to provide a DBTDL content of 5000 parts per million parts of polymer (ppm).

Silane-grafted polymers, prepared as described above, are dry blended with five wt%, based on weight of polymer plus weight of master batch, of the master batch. The resulting dry blend is then converted into ASTM test specimens using an Arburg Model 370C-800-225 (800 kilonewton (KN) hydraulic clamping

force) reciprocating screw injection molding machine (30 millimeter (mm) screw). Injection molding conditions are shown in Table III below.

Table III - Injection Molding Machine Conditions Parameter Setting Zone 1 Temperature (OF/"C) 385/196 Temperature Zones 2-4 (0F/0C) 400/204 Zone 5 Temperature (OF/"C) 410/210 Shot size 58.3 to 58.8 cc Injection Pressure (bar/MPa) 700/70 Hold Pressure (bar/MPa) 150 to 190/15 to 19 Injection Time 1.95 to 2.3 seconds Cooling Time 30 to 40 seconds Screw Injection Velocity 25 meters per minute The silane-grafted injection molded test specimens are separated by a paper towel and placed in a plastic bag that is filled with water, sealed and placed in an oven operating at a set temperature of 50"C for two days to effect crosslinking within the test specimens. The samples are then removed from the bags and towel dried before being subjected to physical property testing as follows: a) % gel (ASTM D-2765), b) Shore A Hardness (ASTM D- 2240), c) Tensile Strength (ASTM D-638), d) Elongation (ASTM D- 638), e) NBS Abrasion (ASTM D-1630) and f) Coefficient of Friction (COF) using mason tile (dry and wet) (ASTM D-1894). Physical property test results are summarized in Table V below.

Table IV shows component ratios for the silane-grafted, injection molded and crosslinked test specimens. The component ratios reflect the amounts of each component without taking into account any polymer used in the master batch. Polypropylene (PP), where added, is commercially available from Himont under the trade designation ProfaxB 6323.

Three Comparative Examples are shown in Table V together with Examples 1-14 that represent the present invention.

Comparative Examples A, B and C have, respectively, the same component ratios as Examples 2, 11 and 12, but they are not silane-grafted and crosslinked. Example 13 is a blend of 50 wt% of the material of Example 12 and 50 wt% of the material of Comparative Example C. Example 14 is a blend of 25 wt% of the material of Example 12 and 75 wt% of the material of Comparative Example C.

Table IV Component Ratios Compo- Ex Ex Ex Ex Ex Ex Ex Ex Ex Ex Ex Ex nent 1 2 3 4 5 6 7 8 9 10 11 12 Poly- -- -- -- 20 14 20 14 -- -- -- -- -- mer A Poly- 100 -- -- -- -- 80 56 95 72 60 -- -- mer C Poly- -- 100 90 80 56 -- -- -- -- -- 90 63 mer D PP -- -- 10 -- -- -- -- 5 13 10 10 7 Oil -- -- -- -- 30 -- 30 -- 15 30 -- 30

Table V - Physical Property Test Results Ex Tensile Elonga- Gel Hard- NBS COF COF (psi/ tion (wt%) ness Abra- (Dry (Wet MPa) (%) (Shore sion Tile) Tile) A) 1 490/3.4 140 98 62 40 1.07 0.70 2 690/4.8 320 84 73 80 0.77 0.47 A 669/4.6 755 0 76 48 0.69 0.46 3 790/5.4 280 91 78 140 0.90 0.49 4 780/5.4 240 96 80 165 N.D. N.D. 5 370/2.6 240 57 58 75 N.D. N.D. 6 680/4.7 180 94 72 75 N.D. N.D. 7 360/2.5 170 60 58 62 N.D. N.D. 8 530/3.7 141 96 64 155 0.91 0.59 9 373/2.6 131 83 56 124 1.16 0.57 10 549/3.8 186 76 64 143 1.05 0.56 11 793/5.5 276 91 78 143 0.90 0.49 B 878/6.1 990 0 80 60 0.89 0.49 12 501/3.5 347 63 59 96 1.02 0.45 C 393/2.7 815 0 60 67 0.82 0.42 13 680/4.7 689 43 57 56 1.50 0.38 14 618/4.3 >1000 24 56 47 1.38 0.32 N.D. = Not Determined The data in Table V demonstrate that compositions representative of the present invention provide physical properties, especially Shore A hardness and COF (wet mason tile), that are typically required for end use applications such as athletic and industrial footwear. Other physical properties, such as tensile and elongation, are acceptable for the same applications. By way of contrast, Comparative Example A, prepared from the same materials and using the same material ratios as Example 2, but without silane grafting and crosslinking, has a gel content of 0, a

comparable Hardness (Shore A) value and a similar COF value, but a markedly lower NBS abrasion value. "Markedly lower" means at least 25% lower, more often at least 50% lower.

When test samples are prepared as above, but with a polymer having a Hardness (Shore A) before grafting and crosslinking of more than 85, Hardness (Shore A) values increase relative to the same polymer without grafting and crosslinking, while NBS Abrasion values decrease relative to the same polymer without grafting and crosslinking. Similar results are expected for other compositions of the present invention.