NEW SILICOALUMINOPHOSPHATES HAVING AN AEL STRUCTURE, A METHOD FOR THEIR PREPARATION AND THEIR USE AS NAPHTHA CRACKING CATALYSTS FIELD OF THE INVENTION This invention relates to silicoaluminophosphates (SAPOs) having a high catalytic cracking activity, a method for their preparation, and their use as naphtha cracking catalysts. More particularly, the new SAPOs, designated herein as ECR-42, have a high silica: alumina ratio and a beneficial silicon atom distribution that leads to high catalytic activity and selectivity.

BACKGROUND OF THE INVENTION The need for low emissions fuels has created an increased demand for light olefins for use in alkylation, oligomerization, MTBE and ETBE synthesis processes. In addition, a low cost supply of light olefins, particularly propylene, continues to be in demand to serve as feedstock for polyolefin, particularly polypropylene production.

Conventional fluidized and fixed bed processes may be used for increasing olefin production. For example, U. S. Patent No. 4,830,728 discloses an FCC unit that is operated to maximize olefin production. The FCC unit has two separate risers into which a different feed stream is introduced. The operation of the risers is designed so that a suitable catalyst will act to convert a heavy gas oil in one riser and another suitable catalyst will act to crack a lighter olefin/naphtha feed in the other riser. Conditions within the heavy gas oil riser can be modified to maximize either gasoline or olefin production. The primary means of maximizing production of the desired product is by using a specified catalyst.

Conventional hydrocarbon conversion processes may utilize crystalline zeolites as catalysts. Crystalline zeolites have been found to be effective for a wide variety of hydrocarbon conversion processes including the catalytic conversion of naphthas to produce light (C2 to C4) olefins.

Conventionally, crystalline zeolite is incorporated into a matrix in order to form a catalytic cracking catalyst.

Also, U. S. Pat. No. 5,026,936 to Arco teaches a process for the <BR> <BR> <BR> <BR> preparation of propylene from C4 or higher feeds by a combination of cracking and metathesis wherein the higher hydrocarbon is cracked to form ethylene and propylene and at least a portion of the ethylene is metathesized to propylene.

See also, U. S. Pat. Nos. 5,026,935; 5,171,921 and 5,043,522.

U. S. Patent No. 5,069,776 teaches a process for the conversion of a hydrocarbonaceous feedstock by contacting the feedstock with a moving bed of a zeolitic catalyst comprising a zeolite with a pore diameter of 0.3 to 0.7 nm, at a temperature above about 500°C and at a residence time less than about 10 seconds. Olefins are produced with relatively little saturated gaseous hydrocarbons being formed. Also, U. S. Patent No. 3,928,172 tc Mobil teaches a process for converting hydrocarbonaceous feedstocks wherein olefins are produced by reacting said feedstock in the presence of a ZSM-5 catalyst.

There remains a need, though, for more active and selective catalysts useful for catalytically converting naphtha into light olefins, especially propylene.

Conventional silicoaluminophoshates such as SAPO-11 are catalytically active molecular sieves, especially at high silicon concentrations.

However, such materials are prone to detrimental silicon distribution in the framework at high silicon concentration, above about 0.04 molar Si fraction in the framework, resulting in a diminished catalytic activity. Moreover, even materials with a favorable Si distribution in the framework may undergo an undesirable redistribution of framework Si during, for example, catalyst regeneration. There is therefore a need for improved silicoaluminophoshates that have increased catalytic activity at high silicon concentration, and improved activity maintenance characteristics.

SUMMARY OF THE INVENTION In one embodiment, the invention is a process for selectively <BR> <BR> producing C2 to C4 olefins, the process comprising contacting, under catalytic conversion conditions, a catalytically or thermally cracked naphtha containing paraffins and olefins with a catalyst composition containing a molecular sieve with a framework tetrahedra of silicon, aluminum, and phosphorus, the molecular sieve having a total silicon amount ranging from above about 4 molar percent to about 20 molar percent, a total aluminum amount ranging from about 40 molar percent to about 55 molar percent, and a total phosphorus amount ranging from about 30 molar percent to about 50 molar percent, the molar percents being based on the total amount of aluminum, phosphorus, and silicon present in the composition, and the molecular sieve having the topology AEL and being isostructural with conventional SAPO-11, wherein (a) the silicon present in the molecular sieve and the conventional SAPO-11 is distributed among silicon sites in the framework tetrahedra, each site having a first, a second, a third, and a fourth nearest neighbor position, and each nearest neighbor position being independently occupied by one atom selected from silicon, and aluminum, and (b) the molecular sieve has a substantially smaller number of silicon sites having silicon atoms among all four nearest neighbor positions than the conventional SAPO-11 having the same total silicon amount.

In another embodiment, the invention is a process for selectively <BR> <BR> producing C2 to C4 olefins, the process comprising contacting, under catalytic conversion conditions, a catalytically or thermally cracked naphtha containing paraffins and olefins with a molecular sieve, the molecular sieve having a framework tetrahedra of silicon, aluminum, and phosphorus, a total silicon amount ranging from about 4 molar percent to about 20 molar percent, a total aluminum amount ranging from about 40 molar percent to about 55 molar percent, and a total phosphorus amount ranging from about 30 molar percent to about 50 molar percent, the molar percents being based on the total amount of aluminum, phosphorus, and silicon present in the composition, and the molecular sieve having the topology AEL and being isostructural with conventional SAPO-11, wherein (a) the molecular sieve has a first number of Si atoms coordinated as Si(4Si), (b) the conventional SAPO-11 with the Si amount has a second number of Si atoms coordinated as Si (4Si), and (c) the first number of Si atoms is substantially less than the second number of Si atoms.

In one embodiment, the invention is a composition comprising a major amount of a large-pore zeolite catalyst and a minor amount of a molecular sieve composition with a framework tetrahedra of silicon, aluminum, and phosphorus, the molecular sieve having a total silicon amount ranging from about 4 molar percent to about 20 molar percent, a total aluminum amount ranging from about 40 molar percent to about 55 molar percent, and a total phosphorus amount ranging from about 30 molar percent to about 50 molar percent, the molar percents being based on the total amount of aluminum, phosphorus, and silicon present in the composition, and the molecular sieve having the topology AEL and being isostructural with conventional SAPO-11, wherein (a) the silicon present in the molecular sieve and the conventional SAPO-11 is distributed among silicon sites in the framework tetrahedra, each site having a first, a second, a third, and a fourth nearest neighbor position, and each nearest neighbor position being independently occupied by one atom selected from silicon, and aluminum, and (b) the molecular sieve has a substantially smaller number of silicon sites having silicon atoms among all four nearest neighbor positions than the conventional SAPO-11 with the total silicon amount.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 schematically shows the type of silicon environments in SAPO-type molecular sieves.

Figure 2 shows a representative deconvolution of an 29Si NMR spectrum.

Figure 3 shows the 29Si NMR spectra of conventionally prepared SAPO-11. Spectrum 3 (a) shows a SAPO-11 of 5 molar percent Si having about 1/3 of the Si atoms located in silicon islands. Spectrum 3 (b) is a SAPO-11 of 4 molar % Si having at most a small amount of Si located in Si islands, and spectrum 3 (c) shows a SAPO-11 of 14 molar % Si having extensive Si island formation.

Figure 4 shows powder x-ray diffraction data for the AEL-type SAPOs prepared in examples 1 through 4.

Figure 5-shows powder x-ray diffraction data from AEL-type SAPOs of examples 5 through 8.

Figure 6 (a) shows scanning electron micrographs of an AEL-type SAPO prepared in accordance with the method of Example ( ?), and figure 6 (b) shows an electron micrograph of conventionally-prepared SAPO-11.

Figure 7 shows the 29Si NMR spectra of ECR-42 having framework silicon in amounts ranging from about 5 molar % to about 13 molar %. Spectrum 7 (a) shows ECR-42 with about 13 molar percent Si and having about 9% of the Si atoms located in silicon islands, representing a substantially reduced amount of framework Si in islands compared to conventional SAPO-11 of about the same Si content (Figure 3 (c). Spectrum 7 (b) is of ECR-42 of example 6 containing about 7 molar % Si and having about 10% of the Si located in Si islands, and spectrum 7 (c) shows a ECR-42 of example 1 containing about 4 molar % Si having about 4% of the Si located in Si islands.

DETAILED DESCRIPTION OF THE INVENTION The invention is based in part on the discovery that (1) SAPO materials having the AEL structure and designated ECR-42 herein may be prepared as small crystals with high silicon concentration and without undesirable silicon island formation, (2) such materials have high activity and selectivity for cracking naphtha-boiling range hydrocarbons ("naphtha") into light olefins such as propylene, (3) such materials may be prepared with desirable crystallite size and shape, and (4) SAPO precursor gels such as a silicoaluminophosphate gel may be formed from an aqueous synthesis solution containing no added co-solvent or surfactant.

In other words, it has been discovered that modifying the synthesis of a silicon-substituted aluminophosphate by changing the composition of the synthesis mixture, the synthesis conditions, or both, modifies the silicon distribution in the silicoaluminophosphate thus formed. This changed distribution of silicon has a major beneficial influence on the catalytic activity of the silicoaluminophosphate.

The following sections set forth the synthesis and use of the preferred ECR-42 molecular sieves. Section A describes the preferred molecular sieve synthesis processes, Section B describes the preferred molecular sieve catalysts, Section C describes the physical differences between the preferred ECR-42 and conventional SAPO-11, and Section D describes the use of the preferred ECR-42 molecular sieve catalysts in naphtha cracking processes.

A. Synthesis of Preferred AEL-Type SAPO Molecular Sieves When AEL-type molecular sieve materials are synthesized following the procedure described herein, the distribution of Si and therefore the total number and strength of acid sites in the molecular sieve framework is quite different, and much higher than those of previously reported forms of SAPO molecular sieves.

The preferred silicoaluminophosphate composition, ECR-42, has the topology AEL which corresponds to SAPO-11. The AEL topology is defined in the"Atlas of Zeolite Structure Types,"4th Ed, by W. M. Meier, D. H. Olson and Ch. Baerlocher, Elsevier, 1996. Although the composition is isostructural with other AEL molecular sieve materials, it is a distinct molecular sieve composition because the silicon, aluminum, and phosphorus atoms present in a preferred composition of this invention are not arranged the same way as in conventional SAPO-11 molecular sieve. Those skilled in the art will recognize that two isostructural molecular sieves may be entirely different compositions having entirely different properties, depending on, for example, the nature and distribution of the constituent atoms.

Preferred molecular sieve compositions are physically different from other SAPO's having the AEL structure because the silicon atoms are distributed differently in the molecular sieve framework. The physical structure of the preferred composition (and its silicon distribution) is illustrated schematically in figure 1. While the actual structure is three dimensional and contains oxygen in addition to silicon, aluminum and phosphorus, the figure's atomic positions are represented on a two dimensional array and oxygen atoms are omitted for clarity. As is shown in the figure, each lattice site in the framework has four nearest neighbor lattice sites. In the preferred compositions, as with all AEL- type SAPOs, a lattice site occupied by a silicon 4+ cation, i. e., a"silicon site", ordinarily may not have a phosphorus 5+ cation as a nearest neighbor. The four nearest neighbor lattice sites may therefore be occupied by one silicon and three aluminum cations, two silicon and two aluminum cations, three silicon and one aluminum cations, four silicon cations, or four aluminum cations. As discussed, conventional AEL-type SAPOs with increased silicon concentration, above about 4 molar %, contain undesirable silicon islands, i. e., silicon atoms in the framework having four silicon atom nearest neighbors. The silicon atoms in the preferred composition are physically distributed so that the silicon island concentration is greatly reduced compared with conventional SAPO-11 (i. e., SAPO-11 prepared in accordance with the methods disclosed in the prior art) having the same total silicon concentration.

The preferred molecular sieve compositions have both a desirably high silicon concentration and a desirable silicon atom dispersion (i. e. a smaller number of silicon islands than would be present in conventional SAPO-11 with the same silicon content) may be formed in accordance with conventional molecular sieve synthesis techniques. The preferred ECR-42 synthesis processes commence with the formation of a silicoaluminophosphate gel having the formula X, SURF: X2TEMP: A1203: P205: X3SiO2: X4H20: X5SOL wherein SURF is a surfactant capable of forming a microemulsion between synthesis solution's organic and aqueous phases. While not wishing to be bound by any theory or model, it is believed that the surfactant helps to solubilize the organic tetraalkylorthosilicate silica source and also increases the available interface between the organic species and inorganic species in the synthesis gel resulting in an improvement in the final silica distribution in the silicoaluminophosphate product. Non-limiting examples of useful surfactants include one or more of long chain alkylamines such as hexadecylamine, tetradecylamine, dodecylamine, decylamine, or octylamine, or dimethyl alkylamine compounds such as dimethylhexadecylammine or dimethyloctylamine, or trimethylalkylammonium salts such as trimethylhexadecylammounium chloride.

TEMP is a template capable of structure directing to AEL such as di-n- propylamine, diisopropylamine, or diethylamine for forming the preferred ECR- 42 silicoaluminophosphate molecular sieve.

SOL is a water-soluble organic co-solvent capable of solubilizing the organic silicon source. While not wishing to be bound, it is believed that solubilizing organic silicon sources such as a tetraalkylorthosilicate silicon source into the aqueous synthesis gel improves the final silicon distribution in the silicoaluminophosphate product. Non-limiting examples of useful water- soluble organic solvents include one or more of acetone, 1,2-propanediol, 1,3- propanediol, methanol, ethanol, propanol, isopropanol, butanol, or ethylene glycol.

The silicon source material may be any organic silicon species capable of being dispersed or dissolved in an aqueous synthesis solution. As discussed, where an organic silicon species is employed, a water-soluble organic solvent, SOL, is preferably employed. While not wishing to be bound by any theory or model, it is believed dispersing the silicon species in a low molecular weight form in the silicoaluminophosphate synthesis gel improves silicon distribution of the preferred ECR-42 material formed therefrom. Non-limiting examples of useful silicon source materials include one or more of tetraalkylorthosilicates such as tetramethylorthosilicate, tetraethylorthosilicate, tetrapropylorthosilicate, tetrabutylorthosilicate, and silsesquisiloxanes having up to twelve Si centers.

Xi ranges from about 0 to about 0.5, X2 ranges from about 0.1 to about 4, X3 ranges from about 0.01 to about 2, X4 ranges from about 10 to about 100, and X5 ranges from about 0 to about 30. The silicoaluminophosphate gel may be formed in accordance with the following processes.

(I) Processes using surfactant and water-soluble co-solvent.

Silicoaluminophosphate gels having the formula XI SURF: X2 TEMP: A1203: P205: X3 Si02: X4 H20: X5 SOL may be prepared by combining a phosphorus source such as H3P04, ammonium phosphate, and mixtures thereof ; water; and an aluminum source such as hydrated alumina, organo alumina, pseudo-boehmite, aluminum hydroxide, colloidal alumina, and mixtures thereof, and then adding the template in order to form a homogeneous alumino phosphate mixture. The P205: Al203 molar ratio in the alumino phosphate mixture preferably ranges from about 0.7 to about 1.3, and more preferably ranges from about 0.9 to about 1.1. The TEMP: Al203 molar ratio in the alumino phosphate mixture preferably ranges from about 0.1 to about 5, and more preferably from about 0.5 to about 3. A surfactant solution of the surfactant, the-water-soluble organic solvent, and water may then be added to the alumino phosphate mixture along with the organic silicon source and water (if necessary to obtain the desired value of X4) in order to form a synthesis solution having a SURF: Al203 molar ratio preferably ranging from about 0 to about 0.5, and more preferably ranging from about 0.05 to about 0.3.

The relative amounts of the ingredients for the synthesis solution may be calculated from the desired values of X, through Xs. The SOL : Al203 molar ratio in the synthesis solution preferably ranging from about 0 to about 30, and more preferably ranging from about 4 to about 20, and the SiO2: Al203 molar ratio preferably ranging from about 0.01 to about 2.0, and more preferably ranging from about 0.1 to about 0.8. The synthesis solution may then be subjected to gel formation conditions in order to provide the silicoaluminophosphate gel. The ingredients of the synthesis solution, surfactant solution, and alumino phosphate mixture may be mixed in any order. For example, in an alternative embodiment the organic silicon source may be added to a mixture of phosphoric acid and the water-soluble organic solvent. The template and the surfactant may then be added, with the water and aluminum source being added last.

Preferred silicoaluminophosphate crystallization conditions for forming the ECR-42 molecular sieve from the gel include heating the gel in a microwave autoclave for a time sufficient to crystallize the gel. Lower temperature and shorter crystallization times are preferred because such conditions may prevent the formation of undesirable products. Accordingly, the preferred heating times range from about 1 minute to about 5 days, at a temperature ranging from about 100°C to about 250°C, and at a pressure ranging from about 0 bar to about 70 bar. In cases where other products, unreacted gel, or a mixture thereof is present at the conclusion of the reaction, the molecular sieve may be recovered by a separation process such as centrifugation. The process may also include conventional product washing and drying such as an ethanol rinse, followed by a water rinse, followed by air oven drying at a temperature ranging from about ambient temperature to about 200°C. It should be noted that conventional heating, in for example an air oven or an externally heated autoclave, may be substituted for microwave heating in this process, and that a substantially pure ECR-42 molecular sieve composition having the AEL-topology will result with either heating method. When conventional heating is used, the temperature preferably ranges from about 100°C to about 250°C, and more preferably from 150°C to about 200°C.

(II) Processes using surfactant. hexanol co-solvent and microwave heating, Silicoaluminophosphate gels having the formula X, SURF: X2 TEMP: A1203: P205: X3 Si04: X2 H20: X5 SOL' wherein SOL'is a relatively water insoluble organic solvent including solvent mixtures capable forming a microemulsion with water and a surfactant, and including mixtures thereof, may be prepared by according to the method (I) above, except that the water insoluble organic solvent SOL'is substituted for the water-soluble solvent SOL. But for the solvent substitution, the molar ratios of the ingredients in the alumino phosphate mixture and the synthesis solution are as set forth in method (I), and as in that method, the mixing order is not critical.

The preferred ECR-42 molecular sieve composition may be formed from the gel in accordance with the steps set forth in process (I). It should be noted that conventional heating may result in the presence of SAPO-41 material in the molecular sieve composition.

(III) Processes using ethanol with water-soluble cosolvnet and no added surfactant.

Silicoaluminophosphate gels of stoichiometry: X2 TEMP : Al203: P205: X3 Si02: X4 H2O: X5 SOL may be prepared by a method identical to method (I), above, except that no surfactant solution is used. An aqueous solution of water, the water-soluble organic solvent, and the silicon source is used instead of the surfactant solution.

But for the absence of the surfactant, the molar ratios of the ingredients in the alumino phosphate mixture and the synthesis solution are as set forth in method (I), and as in that method, the mixing order of the ingredients is not critical.

The preferred ECR-42 molecular sieve composition may be formed from the gel in accordance with the steps set forth in process (I).

(IV) Processes using an organic silicon source and no added surfactant or water-soluble organic cosolvent.

Silicoaluminophosphate gels of stoichiometry: X2 TEMP: A1203: P205: X3 Si02: X4 H20 may be prepared by a method identical to method (I), above, except that no surfactant and no co-solvent are employed. An aqueous dispersion of water and an organic, water-dispersible silicon source, such as TEOS, and including mixtures thereof, is used instead of the surfactant solution.

But for the absence of the surfactant, the molar ratios of the ingredients in the alumino phosphate mixture and the synthesis solution are as set forth in method (I), and as in that method, the mixing order of the ingredients is not critical.

The preferred ECR-42 molecular sieve composition may be formed from the gel in accordance with the steps set forth in process (I). The product may contain SAPO-31.

(V) Processes for forming SAPO-11 using colloidal silica with no added surfactant and no added solvent.

Silicoaluminophosphate gels of stoichiometry: X2 TEMP: AI203: P205: X3 SiO2: X4 H20 may be prepared by a method identical to method (I), above, except that no surfactant solution is used. An aqueous dispersion of water and the colloidal or fumed silica is used instead of the organic silicon source and surfactant solution.

But for the absence of the surfactant and co-solvent, the molar ratios of the ingredients in the alumino phosphate mixture and the synthesis solution are as set forth in method (I), and as in that method, the mixing order of the ingredients is not critical.

A SAPO-11 molecular sieve composition may be formed from the gel in accordance with the steps set forth in process (I). The product may contain SAPO-31.

The preferred ECR-42 molecular sieve compositions are crystalline, and may be prepared with crystal sizes ranging from about 0.001 micrometers to about 1.0 micrometers. Preferably, crystal size ranges from about 0.01 micrometers to about 0.5 micrometers. The synthesis may be adjusted to prepare crystals of decreased size by diluting the synthesis solution with surfactant, co- solvent, and mixtures thereof. Small crystals may also be prepared by conventional methods such as seeding and high shear agitation rates.

B. Preferred ECR-42 Molecular Sieve Catalysts The ECR-42 molecular sieve materials prepared in accordance with these methods are useful as catalytic materials. While not wishing to be bound, it is believed that the silicon distribution within the molecular sieve crystal, as measured for example by 29Si NMR, is one important characteristic influencing catalytic activity in SAPO materials. Since silicon is responsible for the acidity in SAPO materials, it is desirable that silicon be well dispersed in the aluminophosphate framework for high catalytic activity. Conventional SAPO molecular sieves may contain large silicon islands in the molecular sieve framework. Large silicon islands are undesirable because those silicon atoms at the interior of the islands are catalytically inactive. However, small Si islands are desirable because, it is believed, the strongest acid sites are formed at the borders of the Si islands and the aluminophosphate domains. The presence of these strong acid sites is believed to result from the silicons at the borders having fewer aluminum atoms as nearest neighbors, which would otherwise decreases acidity because aluminum has a lower electronegativity than silicon. The ECR- 42 materials of this invention are believed to possess their desirable catalytic activity and selectivity because the Si atoms are well dispersed within the molecular sieve structure.

As is known to those skilled in the art, molecular sieve materials may possess an intrinsic or added catalytic functionality, and such materials are frequently referred to as"molecular sieve catalysts". Additional catalytic functionalities may be provided for molecular sieve materials by conventional methods. Such methods are applicable to the molecular sieves of this invention, and may be summarized as follows.

Accordingly, the molecular sieve material formed from the gel as set forth above may be calcined to remove the template. The sample may then be allowed to cool, preferably in a dry environment.

C. Structural Analysis of Preferred ECR-42 Molecular Sieve Catalysts As discussed, the preferred ECR-42 compositions are different from SAPO-11 materials known in the art. Preferably, the ECR-42 compositions have a Si content ranging from above about 4 mol. % to about 20 mol. %, more preferably from about 5 mol. % to about 15 mol. %, and still more preferably from about 7 mol. % to about 15 mol %, the silicon content being based on the total amount of Si present in the framework of the molecular sieve composition.

Preferably, more than about 50 molar %, and more preferably more than about 90 molar % of the silicon atoms present in the framework do not have four silicon atoms as nearest neighbors in the framework. See figure 7 (a), (b), and (c). Figure 3 shows the NMR data for conventional SAPO-11 samples with Si contents over approximately the same range as the ECR-42 molecular sieve data in figure 7. A direct comparison of the figures shows that substantially less framework Si in the ECR-42 material is located in Si islands than in the conventional SAPO-11 over the entire range of Si concentration.

In a particularly preferred embodiment, the total molar fraction of silicon in the framework is greater than about 0.05, and the number of Si atoms having no Si nearest neighbor ranges from about 0 mol. % to about 100 mol. %, the number of Si atoms having one Si nearest neighbor ranges from about 5 mol. % to about 25 mol. %, the number of Si atoms having two Si nearest neighbors ranges from about 0 mol. % to about 35 mol. %, the number of Si atoms having three Si nearest neighbors ranges from about 0 mol. % to about 25 mol. %, and the number of Si atoms having four Si nearest neighbors ranging from about 0 mol. % to about 25 mol. %, the mol. % being based on the total silica in the ECR-42.

As is known by those skilled in the art, the distribution of silicon in SAPOs may be measured by 29Si MAS NMR spectroscopy. For example, in SAPO-11, it is known that those silicon atoms having 4 aluminums and 0 silicons (4Al, OSi) as nearest neighbors show as NMR resonance at-86 to-94 ppm chemical shift relative to tetramethylsiliane (TMS). Therefore, the molar percent of Si atoms with zero, one, two, three, and four Si atom nearest neighbors may be obtained, for example, by deconvoluting the integrated intensities from 29Si NMR measurements, as illustrated in Figure 2 and Table 1.

Desirable Si distribution, as shown in the 29Si NMR data of Figure 7 for the preferred ECR-42 material, may be obtained in conventional SAPO-11 molecular sieve material, but only at Si concentrations of 4 wt. % or less. Such a low Si concentration leads to an undesirably diminished catalytic activity, but increasing Si concentration in conventional SAPO-11 leads to the formation of undesirable silicon islands, as shown in figures 3 (a) and (c).

TABLE 1 si Environment 4AI, OSi 3A1, ISi 2A1,2Si lAl, 3Si OA1,4Si Chemical shift in ppm-86 to-95 to-99-100to-105-106to-108-109 to from TMS-94 ppm ppm ppm ppm-115 ppm I The preferred molecular sieves may contain Si concentrations as low as about 1 wt. %. It is often difficult to obtain high quality NMR data from samples of such a low concentration over the whole range of chemical shifts, and consequently some degree of uncertainty may be introduced into the deconvolutions required to determine the number of Si atoms with zero, one, two, three and four nearest neighbors. Nevertheless, the intensity of the-109 to-115 ppm region is sufficient in molecular sieve materials of even 1 wt. % to determine the approximate molar percent of Si framework atoms having four Si atom nearest neighbors, i. e., Si atoms located in the center of Si islands.

X-ray diffraction and electron microscopy may also be used to distinguish the preferred ECR-42 SAPOs from conventional SAPO-11. It is well known that powder X-ray diffraction may be used for determining crystallite size of materials less than about 1000A by the broadening of peaks in the X-ray diffraction pattern.

When the shape of the crystallites is anisotropic (different dimensions in different directions), then the resulting powder diffraction pattern may have both broad and sharp peaks if one or two of the dimensions of the crystals are small enough to show peak broadening. Those reflections coming from Miller planes in the crystals corresponding to the short dimension will have broader peaks than those coming from Miller planes corresponding to the longer dimension will have sharper peaks.

SAPO-11 has an orthorhombic crystal structure, a structure which is frequently associated with spatial anisotropies. The dimensions of the unit cell are a = 8.4A, b = 18.5A and c = 13.5A, and the structure is such that the 10-ring channels run along the direction [100]. The preferred ECR-42 SAPOs may be identified with X-ray diffraction because the shape of the crystallite platelets have an a dimension that is significantly smaller than the b and c dimensions. Consequently, the X-ray diffraction pattern shows the peaks corresponding to the (hO0) reflections to be smaller and broader than those of the (Okl) reflections, as shown in figure 4 (a).

While not wishing to be bound by any model or theory, it is believed that an increased catalytic activity for a molecular sieve catalyst would result when a large number of channel openings are available to allow for efficient transportation of the reacting species and products to and from the active sites inside of, or at the pore mouth of, the molecular sieve crystal. The preferred ECR-42 SAPOs have this desirable spatial anisotropy, as shown in the powder x-ray diffraction results in Figures 4 and 5. The degree of spatial anisotropy can be controlled during synthesis by selecting the appropriate synthesis process. For example, the (200) reflections for the SAPOs prepared in accordance with process (I) (See figures 4 (a), (d), and (e), and figure 5 (a)) are clearly broader in width and shorter in height than surrounding (Okl) reflections of the SAPOs prepared in accordance with processes (II) and (III) (see figures 4 (b) and (c) and figure 5 (b)), and these in turn are broader that the (200) reflections observed for SAPOs prepared in accordance with processes (IV) and (V). See figures 5 (c) and (d). The (200) reflection is located at a scattering angle (26) of about 21. 0° to about 21.2°, for copper Ka.

Electron microscopy may also be used to identify the ECR-42 molecular sieve. The SEM micrograph of Figure 6 (a) clearly shows the preferred thin platelets present in the product of process (I) compared to conventionally prepared SAPO shown in figure 6 (b).

D. Use of ECR-42 Molecular Sieves as Naphtha Cracking Catalysts The preferred ECR-42 catalytic molecular sieve compositions are useful as naphtha cracking catalysts, both alone and in combination with other catalysts, preferably for generating light olefins, and more preferably propylene generation.. A preferred catalyst composition contains about 1 wt. % to about 60 wt. % of one or more SAPO molecular sieves such as ECR-42, SAPO-11, SAPO- 31, and SAPO-41 in an inert inorganic matrix. It may also contain medium-pore silicoalumina zeolite such as ZSM-5, ZSM-22, and ZSM-48. Such catalysts have a dramatically increased catalytic activity for naphtha cracking over conventional catalysts.

The SAPO molecular sieve catalyst may be in the form of particles, and may include fines, inert particles, particles containing a metallic species, and mixtures thereof. Inert particles may contain species such as silica, alumina, clay, and mixtures thereof for use as binders, for example. Particles containing metallic species include platinum compound, platinum metal, and mixtures thereof.

The catalyst particles may contain an inorganic oxide matrix component for binding the particle's components together so that the catalyst particle product is hard enough to survive interparticle and reactor wall collisions. The inorganic oxide matrix may be made according to conventional methods from an inorganic oxide sol or gel which is dried to"glue"the catalyst particle's components together.

Preferably, the inorganic oxide matrix is not catalytically active and comprises oxides of silicon, aluminum, and mixtures thereof. It is also preferred that separate alumina phases be incorporated into the inorganic oxide matrix. Species of aluminum oxyhydroxides-y-alumina, boehmite, diaspore, and transitional aluminas such as a-alumina,-alumina, y-alumina, 6-alumina, s-alumina, K-alumina, and p- alumina can be employed. Preferably, the alumina species is an aluminum trihydroxide such as gibbsite, bayerite, nordstrandite, or doyelite. The matrix material may also contain phosphorous or aluminum phosphate.

The amount of molecular sieve in the catalyst particle will generally range from about 1 to about 60 wt. %, preferably from about 1 to about 40 wt. %, and more preferably from about 5 to about 40 wt. %, based on the total weight of the catalyst. Generally, the catalyst particle size will range from about 10 to 300 microns in diameter, with an average particle diameter of about 60 microns. The surface area of the matrix material will be about <. 350 m2/g, preferably 50 to 200 m2/g, more preferably from about 50 to 100 m2/g. While the surface area of the final catalysts will be dependent on such things as type and amount of molecular sieve used, it will usually be less than about 500 m2/g, preferably from about 50 to 300 m2/g, more preferably from about 50 to 250 m2/g, and most preferably from about 100 to 250 m2/g.

As discussed, the ECR-42 molecular sieve catalysts may be used to convert naphtha into light olefin (preferably propylene) under catalytic conversion conditions that are more specifically described as follows. <BR> <BR> <BR> <BR> <BR> <BR> <P> Feedstreams which are suitable for producing the relatively high C2, C3,<BR> <BR> <BR> <BR> <BR> and C4 olefin yields contain primarily paraffins and olefins. Preferred feedstreams are those boiling in the naphtha range and containing from about 5 wt. % to about 35 wt. %, preferably from about 10 wt. % to about 30 wt. %, and more preferably from about 10 to 25 wt. % paraffins, and from about 15 wt. %, preferably from about 20 wt. % to about 70 wt. % olefins. The feed may also contain species such as diolefins, naphthenes, aromatics, and mixtures thereof.

Naphtha boiling range streams are typically those having a boiling range from about 65°F to about 430°F, preferably from about 65°F to about 300°F. The naphtha can be a thermally cracked or a catalytically cracked naphtha. Such streams can be derived from any appropriate source, for example, they can be derived from the fluid catalytic cracking (FCC) of gas oils and resids, or they can be derived from delayed or fluid coking of resids. It is preferred that the naphtha streams be derived from the fluid catalytic cracking of gas oils and resids. Such naphthas are typically rich in olefins and/or diolefins and relatively lean in paraffins.

Preferably, the processes are performed in a process unit comprised of a reaction zone, a stripping zone, a catalyst regeneration zone, and a fractionation zone. The naphtha feedstream is fed into the reaction zone where it contacts a source of hot, regenerated catalyst. The hot catalyst vaporizes and cracks the feed at a temperature from about 500°C to 650°C, preferably from about 500°C to 600°C. The cracking reaction deposits carbonaceous hydrocarbons, or coke, on the catalyst, thereby deactivating the catalyst. The cracked products are separated from the coked catalyst and sent to a fractionator. The coked catalyst is passed through the stripping zone where volatiles are stripped from the catalyst particles with steam. The stripping can be preformed under low severity conditions in order to retain adsorbed hydrocarbons for heat balance. The stripped catalyst is then passed to the regeneration zone where it is regenerated by burning coke on the catalyst in the presence of an oxygen containing gas, preferably air. Decoking restores catalyst activity and simultaneously heats the catalyst to, e. g., 650°C to 750°C. The hot catalyst is then recycled to the reaction zone to react with fresh naphtha feed. Flue gas formed by burning coke in the regenerator may be treated for removal of particulates and for conversion of carbon monoxide, after which the flue gas is normally discharged into the atmosphere. The cracked products from the reaction zone are sent to a fractionation zone where various products are recovered, particularly a C3 fraction and a C4 fraction.

The preferred catalysts may be used to increase light olefins yields in a primary FCC process unit (i. e., an FCC unit that converts heavy hydrocarbon feeds such as gas oil), in a preferred embodiment the invention uses its own distinct process unit, as previously described, which receives naphtha from a suitable source in the refinery. The reaction zone is operated at process <BR> <BR> conditions that will maximize C2 to C4 olefin, particularly propylene, selectivity<BR> <BR> with relatively high conversion of C ; + olefins to C4-light olefins.

Preferred process conditions include temperatures from about 500°C to about 650°C, preferably from about 525°C to 600°C, hydrocarbon partial pressures from about 10 to 40 psia, preferably from about 20 to 35 psia; and a catalyst to naphtha (wt/wt) ratio from about 3 to 12, preferably from about 4 to 10, where catalyst weight is total weight of the catalyst composite. It is also preferred that steam be concurrently introduced with the naphtha stream into the reaction zone, with the steam comprising up to about 50 wt. % of the hydrocarbon feed. Also, it is preferred that the naphtha residence time in the reaction zone be less than about 10 seconds, for example from about 0.1 to 10 seconds. The above conditions will be such that at least about 60 wt. % of the C5+ olefins in the naphtha stream are converted to C4-products and less than about 25 wt. %, preferably less than about 20 wt. % of the paraffins are converted to C4-products, and that propylene comprises at least about 90 mol %, preferably greater than about 95 mol % of the total C3 reaction products with the weight ratio of propylene/total C2-products greater than about 3.5. It is also preferred that ethylene comprises at least about 90 mol % of the C2 products, with the weight ratio of propylene: ethylene being greater than about 4, and that the"full range"C5+ naphtha product is enhanced in both motor and research octanes relative to the naphtha feed. It is within the scope of this invention that the catalysts be precoked prior to introduction of feed in order to further improve the selectivity to propylene. It is also within the scope of this invention that an effective amount of single ring aromatics be fed to the reaction zone to also improve the selectivity of propylene vs. ethylene. The aromatics may be from an external source such as a reforming process unit or they may consist of heavy naphtha recycle product from the instant process.

The preferred ECR-42 molecular sieve compositions have been tested for naphtha cracking effectiveness using model feeds. Accordingly, an olefin cracking index ("OCI") may be defined based on the WHSV required to achieve 85% olefin conversion in a model feed of about 50 wt. % hexene and about 50 wt. % hexane at about 575°C. The preferred ECR-42 SAPO molecular sieve catalysts generally have an OCI ranging from about 150 hr I to about 5000 hr-'.

In summary, it has been discovered that when ECR-42 molecular sieves are synthesized in accord with the methods described herein, that the distribution of Si and therefore the total number and strength of acid sites is quite different, and much higher, than those of conventional SAPO-11. It has also been discovered that the preferred ECR-42 molecular sieves have augmented naphtha cracking activity without diminishing propylene selectivity compared with conventional SAPO molecular sieve catalysts.

The invention is further exemplified by the following non-limiting examples.

EXAMPLES I. Preparation of the Preferred ECR-42 Molecular Sieves Example 1. Preparation of ECR-42 using surfactant, ethanol co-solvent, and microwave heating.

A silicoaluminophosphate gel of stoichiometry: . 16 CA: DPA: AliOs: P205: 7.3 ethanol (where CA is hexadecylamine) was prepared by mechanically mixing together 28.6 grams of H3PO4 (85%), 25 grams of water and 17 grams of Catapal B alumina (Vista Chemical Co., Houston, Texas 74% Al203,26% H20 for 45 min. in a 500 ml Teflon bottle until homogenous. To this mixture was added 12.7 grams of DPA, and the mixture was then stirred for 30 minutes. A surfactant solution was prepared by mixing 2.4 grams of hexadecylamine in 20.8 grams of ethanol and 12.5 grams of water. This solution was added to half of the di-n- propylamine/aluminophosphate mixture along with 2.6 grams of TEOS and 11.2 grams of water. The resulting mixture was stirred for about 3 min. in a 125 ml blender. This gel was divided between three CEM XP-1500 Teflon microwave autoclaves (about 28.5 grams each), available from CEM Corp., Matthews, NC.

The three autoclaves were heated for 5 min. in a microwave oven to a pressure of 485 psi. After 5,30 and 60 min. at 485 psi the samples were removed from the oven. The ECR-42 products were recovered by centrifugation and washed twice with ethanol and then twice with de-ionized water. The resulting products were dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the products to be pure SAPO-11. See figure 4 (a).

Elemental analysis of the 60 min. sample gave: 17.3% Al; 17.0% P; 1.68% Si, representing a product stoichiometry of Si. 05Al 5lP 44.

Example 2. Preparation of ECR-42 using surfactant, hexanol co-solvent, and microwave heating.

A silicoaluminophosphate gel of stoichiometry: . 16 CA: DPA: A1203: P205: 0.4 Si02: 39 H2O: 4.5 hexanol (where CA is hexadecylamine) was prepared by mechanically mixing together 28.6 grams of H3PO4 (85%), 25 grams of water and 17 grams of Catapal B alumina (Vista, 74% Al203,26% H2O) for 2 hr. in a 500 ml Teflon bottle until homogenous. To this mixture was added 12.7 grams of DPA and the mixture was then stirred for 30 minutes. A surfactant solution was prepared by mixing 4.8 grams of hexadecylamine in 56.9 grams of hexanol and 25 grams of water.

This solution was added to the di-n-propylamine/aluminophosphate mixture along with 10.3 grams of TEOS and 22.3 grams of water. The resulting mixture was stirred for about 3 min. in a 125 ml blender. This gel was divided between two 125 ml Teflon-lined autoclaves and a CEM XP-1500 Teflon microwave autoclave (about 28.5 grams). The two autoclaves were heated at 195°C for 24 and 40 hrs. in a conventional oven. The microwave autoclave was heated for 5 min. in a microwave oven to a pressure of 485 psi. After 60 min. at 485 psi the sample was removed from the oven. The products were recovered by centrifugation and washed twice with ethanol and then twice with de-ionized water. The resulting ECR-42 products were dried in an air oven at 115°C and the powder X-ray diffraction pattern measured showed that the product of the microwave heating was pure SAPO-11 (Figure 4 (c)) and the product of the conventionally heated samples to be SAPO-11 and SAPO-41 (Figure 4 (b)).

Elemental analysis of the microwave heated sample gave: 14.5% Al; 16.4% P; 2.84% Si, representing a product stoichiometry ofSi. o9A1. 46P. 45 and the conventionally heated sample (40 hrs.) gave 15.4% Al; 16.4% P; 3.36% Si, representing a product stoichiometry of Si,, oAl, 47P, 43.

Example 3. Preparation of ECR-42 using surfactant, ethanol co-solvent, and microwave heating.

A silicoaluminophosphate gel of stoichiometry: . 16 CA: DPA: A1203: P205: 0.2 Si02: 39.1 H20: 7.3 ethanol (where CA is hexadecylamine) was prepared by mechanically mixing together 71.5 grams of H3PO4 (85%), 62.5 grams of water and 42.4 grams of Catapal B alumina (Vista, 74% Al203,26% H20) for 45 min. in a 1000 ml Teflon bottle until homogenous. To this mixture was added 31.7 grams of DPA and the mixture was then stirred for 30 minutes. A surfactant solution was prepared by mixing 12 grams of hexadecylamine in 104 grams of ethanol and 62.5 grams of water. This solution was added to the di-n-propylamine/aluminophosphate mixture along with 13 grams of TEOS and 56 grams of water. The resulting mixture was stirred for about 3 min. in a 250 ml blender. One half of this gel was divided between five CEM XP-1500 Teflon microwave autoclaves (about 42.5 grams each). The five autoclaves were heated for 10 min. in a microwave oven to a pressure of 485 psi. After 30 min. at 485 psi the samples were removed from the oven. The ECR-42 products were combined and then recovered by centrifugation and washed twice with ethanol and then twice with de-ionized water. The resulting product was dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the product to be pure SAPO- 11. See figure 4 (d). Elemental analysis gave: 15.96% Al; 17.3% P; 1.638% Si, representing a product stoichiometry of Si. o5Al 49P 46.

Example 4. Preparation of ECR-42 using surfactant, ethanol co-solvent and microwave heating.

A silicoaluminophosphate gel of stoichiometry: . 16 CA: DPA: Al203: P205: 0.4 Si02: 39.1 H2O: 7.3 ethanol (where CA is hexadecylamine) was prepared by adding 6.5 grams more of TEOS to the second half of the gel prepared in Example 3. After thoroughly homogenizing in a blender this gel was divided between five CEM XP-1500 Teflon microwave autoclaves (about 42.5 grams each. The five autoclaves were heated for 10 min. in a microwave oven to a pressure of 485 psi. After 30 min. at 485 psi the samples were removed from the oven. The ECR-42 products were combined and then recovered by centrifugation and washed twice with ethanol and then twice with de-ionized water. The resulting product was dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the product to be pure SAPO-11. See Figure 4 (e). Elemental analysis gave: 15.23% Al; 17.2% P; 2.795% Si, representing a product stoichiometry of Si. 08Al. 46P. 46- Example 5. Preparation of ECR-42 using surfactant, ethanol co-solvent, and conventional heating.

A silicoaluminophosphate gel of stoichiometry: . 16 CA: 2 DPA: Au203: P205: 0.4 Si02: 40 H20: 7.5 ethanol (where CA is hexadecylamine) was prepared by mixing together 25.4 grams of H3PO4 (85%), 35 grams of water, and 15.2 grams of Catapal A alumina (Vista, 74% AI203,26% H20) for 2 min. in a 250 ml plastic beaker. To this mixture was added 22.3 grams of DPA and the mixture was then stirred for 3 minutes. A surfactant solution was prepared by mixing 4.25 grams of hexadecylamine in 38.1 grams of ethanol for thirty minutes. This solution was added to the di-n- propylamine/aluminophosphate mixture along with 9.18 grams of TEOS and 30.6 grams of water. The resulting mixture was homogenized for about 5 min. in a 250 ml blender. About 80 g of this gel was placed in a 125 Teflon lined autoclave. The autoclave was heated for 24 hours in an air oven at 195°C. After cooling, the ECR-42 product was recovered by centrifugation and washed twice with ethanol and then twice with de-ionized water. The resulting product was dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the product to be pure SAPO-11. See Figure 5 (a). Elemental analysis gave: 17.2% Al; 17.1% P; 3.052% Si, representing a product stoichiometryofSi. og4A1. 49iP. 425.

Example 6. Preparation of ECR-42 using TEOS, ethanol co-solvent and conventional heating.

A silicoaluminophosphate gel of stoichiometry: 2 DPA: Al203: P205: 0.4 Si02: 40 H20: 7.5 ethanol was prepared by mixing together 28.9 grams of H3PO4 (85%), 40 grams of water and 17.3 grams of Catapal A alumina (Vista, 74% Al203,26% H20) for 2 min. in a 250 ml plastic beaker. To this mixture was added 25.4 grams of DPA and the mixture stirred for 3 minutes. To the di-n-propylamine/aluminophosphate mixture was added 43.3 grams of ethanol with 10.4 grams of TEOS and 34.7 grams of water. The resulting mixture was homogenized for about 5 min. in a 250 ml blender. About 80 g of this gel was placed in a 125 Teflon lined autoclave. The autoclave was heated for 24 hours in an air oven at 195°C. After cooling, the ECR-42 product was recovered by centrifugation and washed once with ethanol and then three times with de-ionized water. The resulting product was dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the product to be pure SAPO-11. See Figure 5 (b).

Elemental analysis gave: 17.94% Al; 20.1% P; 2.56% Si, representing a product stoichiometry of Si. 065AI. 473P. 462- Example 7. Preparation of ECR-42 using TEOS and conventional heating.

A silicoaluminophosphate gel of stoichiometry: 1.5 DPA: Al203: P205: 0.4 Si02: 50 H20 was prepared by mixing together 25.1 grams of H3PO4 (85%), 36 grams of water and 15 grams of Catapal A alumina (Vista, 74% A1203,26% H2O) for 2 min. in a 250 ml plastic beaker. To this mixture was added 16.5 grams of DPA, and the mixture was stirred for 3 minutes. To the di-n-propylamine/aluminophosphate mixture was added 9.1 grams of TEOS (tetraethylorthosilicate) and 48.4 grams of water. The resulting mixture was homogenized for about 5 min. in a 250 ml blender. One half of this gel was placed in a 125 Teflon-lined autoclave. The autoclave was heated for 24 hours in an air oven at 220°C. After cooling, the ECR-42 product was recovered by centrifugation and washed four times with de-ionized water. The resulting product was dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the product to be SAPO-11 and SAPO-41. See Figure 5 (c). Elemental analysis gave: 18.8% Al; 19.7% P; 2.70% Si, representing a product stoichiometry of Si. 067Al 49P 445.

Example 8. Preparation of SAPO-11 using colloidal silica.

A silicoaluminophosphate gel of stoichiometry: 1.5 DPA: A1203: P205: 0.4 Si02: 50 H2O was prepared by mixing together 31.4 grams of H3PO4 (85%), 80 grams of water and 18.8 grams of Catapal B alumina (Vista, 74% A1203,26% H20) and mechanically stirring for 0.5 hour in a 500 ml Teflon bottle. To this mixture was added 20.7 grams of DPA (di-n-propylamine) and 8.19 g solution of aqueous colloidal silica (duPont Ludox AS-40,40% Si02) and stirred for 1.5 hours.

Finally, 20.9 grams of water were added, and the resulting mixture was homogenized for about 5 min. in a 250 ml blender. This gel was divided between two 125 Teflon-lined autoclaves. The autoclaves were heated for 24 hours in an air oven at 195°C. After cooling, the products were combined and then recovered by centrifugation and washed four times with de-ionized water.

The resulting product was dried in an air oven at 115°C and the powder X-ray diffraction pattern measured which showed the product to be SAPO-11 and SAPO-31. See Figure 5 (d). Elemental analysis a product stoichiometry of Sio. 056Alo. 502Po. 442- Example 9. Use of the preferred ECR-42 SAPOs as naphtha cracking catalysts.

This example is conducted with a model feed in order to demonstrate the effectiveness of ECR-42 and conventional SAPO-11 for catalytic conversion of olefinic naphtha to propylene. As can be seen from table 2, conventional SAPO- 11 has a high selectivity but low catalyst activity for the conversion of naphtha to light olefin.

To illustrate the effectiveness of the preferred ECR-42 SAPO catalyst, a series of tests were conducted with a blend of about 50 wt. % hexene and about 50 wt. % hexane as a feed. The reactor temperature was controlled at 575°C.

Weight hourly space velocity was adjusted until 43 wt. % conversion was reached.

As can be seen from the data presented in the Table 2, the conventionally prepared SAPO-11 (sample A) showed relatively low conversion in naphtha cracking. A WHSV of 14 hr-1 was required to reach 43 wt. % conversion.

In contrast, the preferred ECR-42 material of Examples 4 (sample B) and 5 (sample C) showed high activity. Both catalysts showed 43 wt. % conversion at 600 hr-1 WHSV. Based on these data, it can be estimated that the preferred ECR-42 molecular sieve catalysts are forty times more active than the conventional SAPO-11 sample, without a decrease in selectivity.

TABLE 2 Sample A B C MWHeating No Yes No Conversion, Wt% 43.3 43.2 WHSV,60060014 KeyResults, Wt% Ethylene 2.4 1.7 2.3 Propylene I 32 5. 3 ; s Butenes 515"l577 Lt Sats 3.0 1.9 2.4 Selectivity,% Propylene Examples 10. Preparation of ECR42using various alcohol co-solvents and tetraalkylorthosilicates.

A series of silicoaluminophosphate gels of stoichiometry: X, CA: 2 DPA: Al203: P205: 0.4 Si02: 40 H20: X5 SOL where CA is hexadecylamine and DPA is di-n-propylamine) were prepared by mixing together the appropriate amounts of H3PO4 (85%), water and Catapal A alumina (Vista, 74% AI203 26% H2O) for 2 min. in a 250 ml plastic beaker. To this mixture was added the appropriate amount of DPA (di-n-propylamine) and the mixture stirred for 3 minutes. Then the appropriate amount of alcohol, tetraalkylorthosilicate and water were added to obtain the stoichiometry as indicated in Table 1. The resulting mixtures were homogenized for about 5 min. in a 250 ml blender. One half of this mixture was transferred to 125 Teflon-lined autoclave. To the other half was mixed in 1.5 grams of hexadecylamine and also transferred to 125 Teflon-lined autoclave. The autoclaves were heated for 24 hours in an air oven at 195°C. After cooling the product was recovered by centrifugation and washed twice with ethanol and then twice with de-ionized water. The resulting products were dried in an air oven at 115°C and the powder X-ray diffraction patterns measured which showed the products to be pure ECR- 42. Elemental analyses and product stoichiometries are listed in Table 4.

TABLE 3 Experiment Si number X, X5 SOL source 9 0 11. 5 methanol tetraethylorthosilicate 10.16 11. 5 methanol tetraethylorthosilicate 11 0 6. 1 n-propanol tetraethylorthosilicate 12. 16 6. 1 n-propanol tetraethylorthosilicate 13 0 6. 1 i-propanol tetraethylorthosilicate 14.16 6. 1 i-propanol tetraethylorthosilicate 15 0 5. 0 n-butanol tetraethylorthosilicate 16.16 5. 0 n-butanol tetraethylorthosilicate 17 0 8 ethanol tetramethylorthosilicate 18.16 8 ethanol tetramethylorthosilicate 19 0 8 ethanol tetrapropylorthosilicate 20.16 8 ethanol tetrapropylorthosilicate TABLE 4 molarmolarExperimentmolar %Al%PSiAlPnumber%Si ~~ 3. 213 18. 40 1 19. 37 0. 080 0. 480 0.440 10 3. 870 17. 63 13. 68 0. 112 0. 530 0.358 11 2. 813 20. 73 22.22 0. 063 0. 484 0. 452 12 3. 542 18. 27 15. 00 0. 098 0. 526 0.376 13 3. 147 18. 09 19. 42 0. 080 0. 476 0.445 14 3. 550 18. 65 15. 23 0. 097 0. 528 0.376 15 2. 668 18. 60 19. 70 0. 067 0. 485 0.448 16 3. 360 19. 38 15. 78 0. 089 0. 533 0.378 17 3. 148 18. 31 19. 35 0. 079 0. 479 0.441 18 4. 194 18. 35 12. 98 0. 120 0. 545 0.336 18.0019.240.0790.4770.444193.124 20203.730 0.0970.5280.37515.90 Example11 The materials of experiments 1-20 were subject to 29Si MAS NMR to determine the relative amounts of silicon in the five different environments, i. e., Si (4Si), Si (3Si), Si (2Si), Si (lSi), Si (OSi). The 29Si Magic-angle spinning (MAS) nuclear magnetic resonance (NMR) spectra with proton decoupling were recorded on a Chemagnetics CMXII 500 spectrometer at 99.3 MHz using a 7.5 mm probe spinning at 6 kHz. Typical run conditions were: 800 to 10000 acquisitions; 4 or 5 sec. pulse width; 60 to 120 sec. relaxation delay. Chemical shifts were measured relative to tetramethylsilane (TMS). The spectra were then deconvoluted into the five silicon environments. The molar fractions of each silicon environment are given in Table 5.

TABLE 5 ExampleExample4A1,0Si 1A1,3Si0A1,4Si2A1,2Si 211394154 2 3 4 1916115549 6 33 131022 7 8 36 177 23 3118189924 44151431024 11 12 13 32 5922 31612101441 15 16 151018221735 18 19 20