Title of Invention	A SUPPORTED CATALYST FOR OLEFIN POLYMERIZATION
Abstract	A supported catalyst comprising: (a) (1) a support material; (a) (2) an organometal or metalloid compound wherein the metal or metalloid is selected from the group consisting of magnesium, zinc, boron, aluminum, germanium, tin, lead, and mixtures thereof; and (b) an activator compound comprising: (b)(1) a cation which is capable of reacting with a transitin metal metallocene compound to form a transition metal complex which is catalytically active for the polymerization of alpha-olefins; (b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one substituent comprising a moiety having an active hydrogen; and (c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the formula: wherein M is a group 4 metal; * Cp is a substituted eta-5 bonded cyclopentadienyl ligand which contains from 7 to 30 carbon atoms; PI is a phosphinimine ligand; L is a leaving group ligand; and n is 1 or 2, depending upon the valence of m, with the further provisos that: c) said catalyst contains from 1 to 2,000 mu.mol of activator compound per gram of support material; and d) *Cp is selected from the group consisting of 2-pen-tafluorophenyl cyclopentadienyl, tri- butyl-2- pentafluorophenyl cyclopentadienyl and 2-pentafluorophenyl indenyl.

Title of Invention

A SUPPORTED CATALYST FOR OLEFIN POLYMERIZATION

Abstract

A supported catalyst comprising: (a) (1) a support material; (a) (2) an organometal or metalloid compound wherein the metal or metalloid is selected from the group consisting of magnesium, zinc, boron, aluminum, germanium, tin, lead, and mixtures thereof; and (b) an activator compound comprising: (b)(1) a cation which is capable of reacting with a transitin metal metallocene compound to form a transition metal complex which is catalytically active for the polymerization of alpha-olefins; (b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one substituent comprising a moiety having an active hydrogen; and (c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the formula: wherein M is a group 4 metal; * Cp is a substituted eta-5 bonded cyclopentadienyl ligand which contains from 7 to 30 carbon atoms; PI is a phosphinimine ligand; L is a leaving group ligand; and n is 1 or 2, depending upon the valence of m, with the further provisos that: c) said catalyst contains from 1 to 2,000 mu.mol of activator compound per gram of support material; and d) *Cp is selected from the group consisting of 2-pen-tafluorophenyl cyclopentadienyl, tri- butyl-2- pentafluorophenyl cyclopentadienyl and 2-pentafluorophenyl indenyl.

Full Text	SUPPORTED POLYMERIZATION CATALYSTS TECHNICAL FIELD The present invention relates to supported catalysts suitable for the polymerization of olefins and in particular to supported metallocene catalysts providing advantages for operation in gas phase and slurry processes. BACKGROUND ART In recent years there have been many advances in the production of polyolefin homopolymers and copolymers due to the introduction of metallocene catalysts. Metallocene catalysts offer the advantage of generally a higher activity than traditional Ziegler catalysts and are usually described as catalysts which are single site in nature. There have been developed several different families of metallocene complexes. In earlier years catalysts based on bis (cyclopentadienyl) metal complexes were developed, examples of which may be found in EP 129 368 or EP 206 794. More recently complexes having a single or mono cyclopentadienyl ring have been developed. Certain of such monocyclopentadienyl complexes have been referred to as constrained geometry complexes and examples of these complexes may be found in EP 416 815 or EP 420 436. In both of these complexes the metal atom e.g. zirconium is the highest oxidation state. Other complexes however have been developed in which the metal atom may be in a reduced oxidation state. Examples of both the bis (cyclopentadienyl) and mono (cyclopentadienyl) complexes have been described in WO 96/04290 and WO 95/00526 respectively. The above metallocene complexes are utilized for polymerization in the presence of a cocatalyst or activator. Typically activators are aluminoxanes, in particular methyl aluminoxane or compounds based on boron compounds. Examples of the latter are borates such as trialkyl- substituted ammonium tetraphenyl or tetrafluorophenyl borates. Catalyst systems incorporating such borate activators are described in EP 516 479, EP 418 044 and EP 551 277. The above metallocene complexes may be used for the polymerization of olefins in solution, slurry or gas phase. When used in the gas phase the metallocene complex and/or the activator are suitably supported. Typical supports include inorganic oxides (e.g. silica or alumina) or polymeric supports may alternatively be used. Examples of the preparation of supported metallocene catalysts for the polymerization of olefins may be found in WO 94/26793, WO 95/07939, WO 96/00245, WO 96/04318, WO 97/02297 and EP 642 536. WO 98/27119 describes supported catalyst components comprising ionic compounds comprising a cation and an anion in which the anion contains at least one substituent comprising a moiety having an active hydrogen. In this disclosure supported metallocene catalysts are exemplified in which the catalyst is prepared by treating the aforementioned ionic compound with a trialkylaluminum compound followed by subsequent treatment with the support and the metallocene. WO 98/27119 also describes a method for activating a substantially inactive catalyst precursor comprising (a) an ionic compound comprising a cation and an anion containing at least one substituent comprising a moiety having an active hydrogen; (b) a transition metal compound; and optionally (c) a support by treatment with an organometallic compound thereby forming an active catalyst. Various methods have been utilized to prepare supported catalysts of this type. For example, WO 98/27119 describes several methods of preparing the supported catalysts disclosed therein in which the support is impregnated with the ionic compound. The volume of the ionic compound may correspond from 20 volume percent to greater than 200 volume percent of the total pore volume of the support. In a preferred preparative route the volume of the solution of the ionic compound does not exceed substantially, and is preferably equal to, the total pore volume of the support. Such methods of preparation may be referred to as incipient precipitation or incipient wetness techniques. More recently WO 02/06357 describes an improved incipient wetness technique for the preparation of a supported metallocene catalyst system in which the support is impregnated with an ionic compound and the metallocene complex followed by treatment with an organometallic compound. The preferred metal with respect to the organometallic compound is aluminum and the preferred metal for the ionic activator is boron whereby the molar ratio of Al/B is in the range of 0.1 to 2.0, and is preferably in the range of 0.1 to 0.8, and most preferably in the range of 0.3 to 0.6. The "ionic activators" described above are highly desirable for slurry and gas phase olefin polymerizations especially for the preparation of catalysts which are not as prone to cause reactor fouling as similar catalysts prepared with aluminoxanes. One challenge that remains is to increase the activity/productivity of catalysts that incorporate these activators. We have discovered that certain catalyst molecules having cyclopentadienyl and phosphinimine ligands exhibit excellent activity when the cyclopentadienyl ligand is substituted. The level of substitution should include at least 2 carbon atoms. A preferred maximum level of substitution is 25 carbon atoms (on the 5 carbon atom ring of the cyclopentadienyl ligand) due to steric considerations. DISCLOSURE OF INVENTION The present invention provides a supported catalyst comprising of: (a)(1) a support material; (a)(2) an organometal or metalloid compound wherein the metal or metalloid is selected from the group consisting of magnesium, zinc, boron, aluminum, germanium, tin, lead, and mixtures thereof; and (b) an activator compound comprising: (b)(1) a cation which is capable of reacting with a transition metal metallocene compound to form a transition metal complex which is catalytically active for the polymerization of alpha- olefins; (b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one substituent comprising a moiety having an active hydrogen; and (c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the formula: wherein M is a group 4 metal; Cp is a eta-5 bonded cyclopentadienyl ligand; PI is a phosphinimine ligand having at least one hydrocarbyl substituent containing from one to 20 carbon atoms; L is a leaving group ligand; and n is 1 or 2, depending upon the valence of m. The use of the substituted cyclopentadienyl ligand with the defined supported activator provides an exceptional catalyst. BEST MODE FOR CARRYING OUT THE INVENTION Detailed descriptions of essential catalyst components (namely (i) the support; (ii) the catalyst molecule; and (iii) the organometal/metalloid. Particulate Metal Oxide Support The catalyst of this invention must be prepared with a particulate metal oxide support. The use of metal oxide supports in the preparation of olefin polymerization catalysts is known to those skilled in the art. An exemplary list of suitable metal oxides includes oxides of aluminum, silicon, zirconium, zinc and titanium. Alumina, silica and silica-alumina are metal oxides which are well known for use in olefin polymerization catalysts and are preferred for reasons of cost and convenience. Silica is particularly preferred. It is preferred that the metal oxide have a particle size of from about 1 to about 200 microns. It is especially preferred that the particle size be between about 30 and 100 microns if the catalyst is to be used in a gas phase or slurry polymerization process and that a smaller particle size (less than 10 microns) be used if the catalyst is used in a solution polymerization. Conventional porous metal oxides, which have comparatively high surface areas (greater than 1 m2/g, particularly greater than 100 m2/g, more particularly greater than 200 m2/g), are preferred to non-porous metal oxides. The support material may be subjected to a heat treatment and/or chemical treatment to reduce the water content or the hydroxyl content of the support material. Typically chemical dehydration agents are reactive metal hydrides, aluminum alkyls and halides. Prior to its use the support material may be subjected to treatment at 100°C to 1000°C and preferably at 200 to 850°C in an inert atmosphere under reduced pressure. The support material may be further combined with an organoaluminum compound and most preferably a trialkylaluminum compound in a dilute solvent. The support material is preferably pretreated with the trialkylaluminum compound at a temperature of 20°C to 150°C and preferably at 20°C to 100°C. The molar ration of transition metal in the catalyst compound (which transition metal is preferably titanium or zirconium) to ionic activator employed in the method of the present invention may be in the range 1:10000 to 100:1. A preferred range is from 1:5000 to 10:1 and most preferred from 1:10 to 10:1. 2. CATALYST MOLECULE The catalyst molecule of the present invention is a phosphinimine complex of a group 4 transition metal having at least one phosphinimine ligand (as defined below), at least one leaving group (as defined below) and at least one substituted cyclopentadienyl ligand.. These catalyst molecules are represented by the formula: wherein PI is a phosphinimine ligand; M is a group 4 transition metal; L is an activatable ligand; n is one or two, depending upon the valences of M and L; and Cp is a substituted cyclopentadienyl ligand which is eta-5 bonded with the group 4 transition metal and which contains from 7 to 30 carbon atoms. 2.1 Cp Ligand The Cp ligand is a substituted cyclopentadienyl ligand which contains a total of from 7 to 30 carbon atoms. The use of substituents on such cyclic ligands is well known and is described, for example, in U.S. Patent 5,324,800 (Welborn). An exemplary list of substituents for such Cp ligands includes C1-20 hydrocarbyl groups; substituted C1-20 hydrocarbyl groups wherein one or more hydrogen atoms is replaced by a halogen; an amido group, a phosphido group, or an alkoxy group. The substituent may form a bridge with the phosphinimine ligand. The substituents may be bonded to each other (as in, fro example, an indenyl ligand). As shown in the examples, fluoro-substituted Cp ligands are preferred. A cyclopentadienyl ligand contains 5 carbon atoms in the ring structure. The substituted cyclopentadienyl ligand used in this invention must contain at least 7 carbon atoms, i.e. in addition to the 5 carbon atoms of the cyclopentadienyl ligand, at least 2 extra carbon atoms are required. 2.2 Phosphinimine Ligand The catalyst component of this invention must contain a phosphinimine ligand, which is covalently bonded to the metal. This ligand is defined by the formula: wherein each R" is independently selected from the group consisting of a hydrogen atom, a halogen atom, C1-20 hydrocarbyl radicals which are unsubstituted by or further substituted by a halogen atom, a C1-8 alkoxy radical, a C6-10 aryl or aryloxy radical, an amido radical, a silyl radical of the formula: wherein each R2 is independently selected from the group consisting of hydrogen, C1-8 alkyl or alkoxy radical, C6-10 aryl or aryloxy radicals, and a germanyl radical of the formula: wherein R2 is as defined above. The preferred phosphinimines are those in which each R" is a hydrocarbyl radical. A particularly preferred phosphinimine is tri-(tertiary butyl) phosphinimine (i.e. where each R" is a tertiary butyl group). 2.3 Activatable Ligand The term "activatable ligand" refers to a ligand which may be activated by a cocatalyst (also known as an "activator" to facilitate olefin polymerization. Exemplary activatable ligands are independently selected from the group consisting of a hydrogen atom, a halogen atom, a C1-10 hydrocarbyl radical, a C1-20 alkoxy radical, a C5-10 aryl oxide radical; each of which said hydrocarbyl, alkoxy, and aryl oxide radicals may be unsubstituted by or further substituted by a halogen atom, a C1-8 alkyl radical, a C1-8 alkoxy radical, a C6-10 aryl or aryl oxy radical, an amido radical which is unsubstituted or substituted by up to two C1-8 alkyl radicals; a phosphido radical which is unsubstituted or substituted by up to two C1-8 alkyl radicals. 3. ORGANOMETAL/METALLOID AND IONIC ACTIVATOR The support material is treated with the organometal compound. Suitable organometal compounds are those comprising metals of Groups 2-13, germanium, tin, and lead, and at least two substituents selected from hydride, hydrocarbyl radicals, trihydrocarbyl silyl radicals, and trihydrocarbyl germyl radicals. Additional substituents preferably comprise one or more substituents selected from hydride, hydrocarbyl radicals, trihydrocarbyl substituted silyl radicals, trihydrocarbyl substituted germyl radicals, and hydrocarbyl-, trihydrocarbyl silyl- or trihydrocarbyl germyl- substituted metalloid radicals. The recitation "metalloid", as used herein, includes non-metals such as boron, phosphorus and the like which exhibit semi-metallic characteristics. Examples of such organometal compounds include organomagnesium, organozinc, organoboron, organoaluminum, organogermanium, organotin, and organolead compounds, and mixtures thereof. Further suitable organometal compounds are alumoxanes. Preferred examples are alumoxanes and compounds represented by the following formulae: MgR12, ZnR12, BR1xR2y, AIR1xR2y, wherein R1 independently each occurrence is hydride, a hydrocarbyl radical, a trihydrocarbyl silyl radical, a trihydrocarbyl germyl radical, or a trihydrocarbyl-, trihydrocarbyl silyl-, or trihydrocarbyl germyl-substituted metalloid radical, R2 independently is the same as R1, x is 2 or 3, y is 0 or 1 and the sum of x and y is 3, and mixtures thereof. Examples of suitable hydrocarbyl moieties are those having from 1 to 20 carbon atoms in the hydrocarbyl portion thereof, such as alkyl, aryl, alkaryl, or aralkyl. Preferred radicals include methyl, ethyl, n- or i-propyl, n-, s- or t-butyl, phenyl, and benzyl. Preferably, the aluminum component is selected from the group consisting of alumoxane and aluminum compounds of the formula AIR1X wherein R1 in each occurrence independently is hydride or a hydrocarbyl radical having from 1 to 20 carbon atoms, and x is 3. Suitable trihydrocarbyl aluminum compounds are trialkyl or triaryl aluminum compounds wherein each alkyl or aryl group has from 1 to 10 carbon atoms, or mixtures thereof, and preferably trialkyl aluminum compounds such as trimethyl, triethyl, tri-isobutyl aluminum. Alumoxanes (also referred to as aluminoxanes) are oligomeric or polymeric aluminum oxy compounds containing chains of alternating aluminum and oxygen atoms, whereby the aluminum carries a substituent, preferably an alkyl group. The structure of alumoxane is believed to be represented by the following general formulae (-AI(R)-O)m, for a cyclic alumoxane, and R2 AI--O(--AI(R)--O)m--AIR2, for a linear compound, wherein R independently in each occurrence is a C1-C10 hydrocarbyl, preferably alkyl, or halide and m is an integer ranging from 1 to about 50, preferably at least about 4. Alumoxanes are typically the reaction products of water and an aluminum alkyl, which in addition to an alkyl group may contain halide or alkoxide groups. Reacting several different aluminum alkyl compounds, such as, for example, trimethyl aluminum and tri-isobutyl aluminum, with water yields so-called modified or mixed alumoxanes. Preferred alumoxanes are methylalumoxane and methylalumoxane modified with minor amounts of other lower alkyl groups such as isobutyl. Alumoxanes generally contain minor to substantial amounts of starting aluminum alkyl compound. The way in which the alumoxane is prepared is not critical. When prepared by the reaction between water and aluminum alkyl, the water may be combined with the aluminum alkyl in various forms, such as liquid, vapor, or solid, for example in the form of crystallization water. Particular techniques for the preparation of alumoxane type compounds by contacting an aluminum alkyl compound with an inorganic salt containing water of crystallization are disclosed in U.S. Patent 4,542,199. In a particular preferred embodiment an aluminum alkyl compound is contacted with a regeneratable water-containing substance such as hydrated alumina, silica or other substance. This is disclosed in European Patent Application No. 338,044. The supported catalyst component and supported catalyst of the present invention generally comprise a support material combined or treated with the organometal compound, preferably an aluminum component, and containing at least 0.1 micromol of organometal compound per g of support material, typically at least 5 micromole per g support material, advantageously at least 0.5 weight percent of the metal, preferably aluminum, expressed in gram of metal, preferably aluminum, atoms per g of support material. Preferably, the amount of metal, advantageously aluminum, is at least 2 weight percent, and generally not more than 40 weight percent, and more preferably not more than 30 weight percent. At too high amounts of metal, preferably aluminum, the supported catalyst becomes expensive. At too low amounts the catalyst efficiency goes down to drop below acceptable levels. The supported catalyst component and supported catalyst of the present invention preferably contain a treated support material (a) comprising a support material and an alumoxane wherein not more than about 10 percent aluminum present in the treated support material is extractable in a one hour extraction with toluene of 90°C using about 10 ml_ toluene per gram of pretreated support material. More preferably, not more than about 9 percent aluminum present in the supported catalyst component is extractable, and most preferably not more than about 8 percent. This is especially advantageous when the supported catalyst component or catalyst prepared therefrom is used in a polymerization process where a diluent or solvent is used which may extract non-fixed alumoxane from the support material. It has been found that when the amount of extractables is below the levels given above, the amount of alumoxane that can diffuse into the polymerization solvent or diluent, if used, is so low that no appreciable amount of polymer will be formed in the diluent, as compared to polymer formed on the support material. If too much polymer is formed in the diluent the polymer bulk density will decrease below acceptable levels and reactor fouling problems may occur. The toluene extraction test is carried out as follows: About 1 g of supported catalyst component or supported catalyst, with a known aluminum content, is added to 10 mL toluene and the mixture is then heated to 90°C under an inert atmosphere. The suspension is stirred well at this temperature for 1 hour. Then the suspension is filtered applying reduced pressure to assist in the filtration step. The solids are washed twice with about 3 to 5 mL toluene of 90°C per gram of solids. The solids are then dried at 120°C for 1 hour, and subsequently the aluminum content of the solids is measured. The difference between the initial aluminum content and the aluminum content after the extraction divided by the initial aluminum content and multiplied by 100%, gives the amount of extractable aluminum. The aluminum content can be determined by slurrying about 0.5 g of supported catalyst component or supported catalyst in 10 mL hexane. More specifically, preferred activator compounds contain a compatible anion having up to 100, and preferably up to 50 non-hydrogen atoms and having at least one substituent comprising an active hydrogen moiety. Preferred substituents comprising an active hydrogen moiety correspond to the formula: wherein G is a polyvalent hydrocarbon radical, T is O, S, NR, or PR, wherein R is a hydrocarbyl radical, a trihydrocarbyl silyl radical, a trihydrocarbyl germyl radical, or hydrogen, H is hydrogen, q is 0 or 1, and preferably 1, and r is an integer from 1 to 3, preferably 1. Polyvalent hydrocarbon radical G has r+1 valencies, one valency being with a metal or metalloid of the Groups 5-15 of the Periodic Table of the Elements in the compatible anion, the other valency or valencies of G being attached to r groups T--H. Preferred examples of G include divalent hydrocarbon radicals such as: alkylene, arylene, aralkylene, or alkarylene radicals containing from 1 to 20 carbon atoms, more preferably from 2 to 12 carbon atoms. Suitable examples of G include phenylene, biphenylene, naphthylene, methylene, ethylene, 1,3-propylene, 1,4-butylene, phenylmethylene (--C6H4--CH2--). The polyvalent hydrocarbyl portion G may be further substituted with radicals that do not interfere with the coupling function of the active hydrogen moiety. Preferred examples of such noninterfering substituents are alkyl, aryl, alkyl- or aryl-substituted silyl and germyl radicals, and fluoro substituents. The group T--H in the previous formula thus may be an -OH, --SH, -NRH, or --PRH group, wherein R preferably is a C1-18, preferably a C1-10 hydrocarbyl radical or hydrogen, and H is hydrogen. Preferred R groups are alkyls, cycloalkyls, aryls, arylalkyls, or alkylaryls of 1 to 18 carbon atoms, more preferably those of 1 to 12 carbon atoms. The -OH, --SH, -NRH, or --PRH groups may be part of a larger functionality such as, for example, C(O)-OH, C(S)~SH, C(O)~NRH, and C(O)~PRH. Most preferably, the group T--H is a hydroxy group, -OH, or an amino group, -NRH. Very preferred substituents Gq(T-H)r comprising an active hydrogen moiety include hydroxy- and amino-substituted aryl, aralkyl, alkaryl or alkyl groups, and most preferred are the hydroxyphenyls, especially the 3- and 4-hydroxyphenyl groups, hydroxytolyls, hydroxy benzyls (hydroxymethylphenyl), hydroxybiphenyls, hydroxynaphthyls, hydroxycyclohexyls, hydroxymethyls, and hydroxypropyls, and the corresponding amino-substituted groups, especially those substituted with -NRH wherein R is an alkyl or aryl radical having from 1 to 10 carbon atoms, such as for example methyl, ethyl, propyl, i-propyl, n-, i-, or t-butyl, pentyl, hexyl, heptyl, octyl, nonyl, and decyl, phenyl, benzyl, tolyl, xylyl, naphthyl, and biphenyl. The compatible anion containing the substituent which contains an active hydrogen moiety, may further comprise a single Group 5-15 element or a plurality of Group 5-15 elements, but is preferably a single coordination complex comprising a charge-bearing metal or metalloid core, which anion is bulky. A compatible anion specifically refers to an anion which when functioning as a charge balancing anion in the catalyst system of this invention, does not transfer an anionic substituent or fragment thereof to the transition metal cation thereby forming a neutral transition metal compound and a neutral metal by-product. "Compatible anions" are anions which are not degraded to neutrality when the initially formed complex decomposes and are non-interfering with desired subsequent polymerizations. Preferred anions are those containing a single coordination complex comprising a charge-bearing metal or metalloid core carrying a substituent containing an active hydrogen moiety which anion is relatively large (bulky), capable of stabilizing the active catalyst species (the transition metal cation) which is formed when the activator compound and transition metal compound are combined and said anion will be sufficiently labile to be displaced by olefinic, diolefinic and acetylenically unsaturated compounds or other neutral Lewis bases such as ethers, nitrites and the like. Suitable metals for the anions of activator compounds include, but are not limited to, aluminum, gold, platinum and the like. Suitable metalloids include, but are not limited to, boron, phosphorus, silicon and the like. Activator compounds which contain anions comprising a coordination complex containing a single boron atom and a substituent comprising an active hydrogen moiety are preferred. Preferably, compatible anions containing a substituent comprising an active hydrogen moiety may be represented by the following general Formula (I): wherein M' is a metal or metalloid selected from Groups 5-15 of the Periodic Table of the Elements; Q independently in each occurrence is selected from the group consisting of hydride, dihydrocarbylamido, preferably dialkylamido, halide, hydrocarbyloxide, preferably alkoxide and aryloxide, hydrocarbyl, and substituted-hydrocarbyl radicals, including halo-substituted hydrocarbyl radicals, and hydrocarbyl- and halohydrocarbyl-substituted organo-metalloid radicals, the hydrocarbyl portion having from 1 to 20 carbons with the proviso that in not more than one occurrence is Q halide; G is a polyvalent, having r+1 valencies and preferably divalent hydrocarbon radical bonded to M' and T; T is O, S, NR, or PR, wherein R is a hydrocarbon radicals a trihydrocarbyl silyl radical, a trihydrocarbyl germyl radical, or hydrogen; m is an integer from 1 to 7, preferably 3; n is an integer from 0 to 7, preferably 3; q is an integer 0 or 1, preferably 1; r is an integer from 1 to 3, preferably 1; z is an integer from 1 to 8, preferably 1; d is an integer from 1 to 7, preferably 1; and n+z-m=d. Preferred boron-containing anions which are particularly useful in this invention may be represented by the following general Formula (II): wherein B is boron in a valence state of 3; z' is an integer from 1-4, preferably 1; d is 1; and Q, G, T, H, q, and r are as defined for Formula (I). Preferably, z' is 1, q is 1, and r is 1. Illustrative, but not limiting, examples of anions of activator compounds to be used in the present invention are boron-containing anions such as triphenyl(hydroxyphenyl)borate, diphenyl- di(hydroxyphenyl)borate, triphenyl(2,4-dihydroxyphenyl)borate, tri(p- tolyl)(hydroxyphenyl)borate, tris- (pentafluorophenyl)(hydroxyphenyl)borate, tris-(2,4- dimethylphenyl)(hydroxyphenyl)borate, tris-(3,5- dimethylphenyl)(hydroxyphenyl)borate, tris-(3,5-di- trifluoromethylphenyl)(hydroxyphenyl)borate, tris(pentafluorophenyl)(2- hydroxyethyl)borate, tris(pentafluorophenyl)(4-hydroxybutyl)borate, tris(pentafluorophenyl)(4-hydroxycyclohexyl)borate, tris(pentafluorophenyl)(4-(4'-hydroxyphenyl)phenyl)borate, tris(pentafluorophenyl)(6hydroxy-2-naphthyl)borate, and the like. A highly preferred activator complex is tris(pentafluorophenyl)(4- hydroxyphenyl)borate. Other preferred anions of activator compounds are those above mentioned borates wherein the hydroxy functionality is replaced by an amino NHR functionality wherein R preferably is methyl, ethyl, or t-butyl. The cationic portion b.1) of the activator compound to be used in association with the compatible anion b.2) can be any cation which is capable of reacting with the transition metal compound to form a catalytically active transition metal complex, especially a cationic transition metal complex. The cations b.1) and the anions b.2) are used in such ratios as to give a neutral activator compound. Preferably the cation is selected from the group consisting of Bronsted acidic cations, carbonium cations, silylium cations, and cationic oxidizing agents. Bronsted acidic cations may be represented by the following general formula: wherein L is a neutral Lewis base, preferably a nitrogen, phosphorus, or sulfur containing Lewis base; and (L-H)+ is a Bronsted acid. The Bronsted acidic cations are believed to react with the transition metal compound by transfer of a proton of said cation, which proton combines with one of the ligands on the transition metal compound to release a neutral compound. Illustrative, but not limiting, examples of Bronsted acidic cations of activator compounds to be used in the present invention are trialkyl- substituted ammonium cations such as triethylammonium, tripropylammonium, tri(n-butyl)ammonium, trimethylammonium, tributylammonium, and tri(n-octyl)ammonium. Also suitable are N,N- dialkyl anilinium cations such as N,N-dimethylanilinium, N,N- diethylanilinium, N,N-2,4,6-pentamethylanilinium, N,N- dimethylbenzylammonium and the like; dialkylammonium cations such as di-(i-propyl)ammonium, dicyclohexylammonium and the like; and triarylphosphonium cations such as triphenylphosphonium, tri(methylphenyl)phosphonium, tri(dimethylphenyl)phosphonium, dimethylsulphonium, diethylsulphonium, and diphenylsulphonium. Particularly suitable are those cations having longer alkyl chains such as dihexydecylmethylammonium, dioctadecylmethylammonium, ditetradecylmethylammonium, bis (hydrogenated tallow alkyl) methylammonium and similar. Particular preferred activators of this type are alkylammonium tris (pentaflurorphenyl) 4-(hydroxyphenyl) borates. A particularly preferred activator is bis (hydrogenated tallow alkyl) methyl ammonium tris (pentafluorophenyl) (4-hydroxyphenyl) borate. A second type of suitable cations corresponds to the formula: C+ wherein C+ is a stable carbonium or silylium ion containing up to 30 non- hydrogen atoms, the cation being capable of reacting with a substituent of the transition metal compound and converting it into a catalytically active transition metal complex, especially a cationic transition metal complex. Suitable examples of cations include tropyllium, triphenylmethylium, benzene(diazonium). Silylium salts have been previously generically disclosed in J. Chem. Soc. Chem. Comm., 1993, 383-384, as well as Lambert, J. B., et al., Organometallics, 1994, 13, 2430-2443. Preferred silylium cations are triethylsilylium, and trimethylsilylium and ether substituted adducts thereof. Another suitable type of cation comprises a cationic oxidizing agent represented by the formula: wherein Oxe+ is a cationic oxidizing agent having a charge of e+, and e is an integer from 1 to 3. Examples of cationic oxidizing agents include: ferrocenium, hydrocarbyl-substituted ferrocenium, Ag+, and Pb2+. The quantity of activator compound in the supported catalyst component and the supported catalyst is not critical, but typically ranges from 0.1, preferably from 1 to 2,000 micromoles of activator compound per gram of treated support material. Preferably, the supported catalyst or component contains from 10 to 1,000 micromoles of activator compound per gram of treated support material. The supported catalyst component of the present invention as such or slurried in a diluent can be stored or shipped under inert conditions, or can be used to generate the supported catalyst of the present invention. With respect to this type of activator, a particularly preferred compound is the reaction product of an alkylammonium tris (pentafluorophenyl)-4-(hydroxyphenyl) borate and an organometallic compound, for example trimethylaluminum. Thus according to another aspect of the present invention there is provided a process for the polymerization of olefin monomers selected from (a) ethylene, (b) propylene, (c) mixtures of ethylene and propylene, and (d) mixtures of (a), (b), or (c) with one or more other alpha olefins, said process performed in the presence of a supported transition metal catalyst system as hereinbefore described. The supported transition metal catalysts of the present invention may be used for the polymerization of olefins in solution, slurry or the gas phase. A slurry process typically uses an inert hydrocarbon diluent and temperatures from about 0°C up to a temperature just below the temperature at which the resulting polymer becomes substantially soluble in the inert polymerization medium. Suitable diluents include toluene or alkanes such as hexane, propane or isobutane. Preferred temperatures are from about 30°C up to about 200°C but preferably from about 60°C to 100°C. Loop reactors are widely used in slurry polymerization processes. The preferred process for the present invention is the gas phase. Suitable gas phase processes of the present invention include the polymerization of alpha olefins, especially for the homopolymerization and the copolymerization of ethylene with alpha olefins for example 1-butene, 1-hexene, 4-methyl-1-pentene are well known in the art. Particularly preferred gas phase processes are those operating in a fluidized bed. Examples of such processes are described in EP 89691 and EP 699213, the latter being a particularly preferred process for use with the supported catalysts of the present invention. Particularly preferred polymerization processes are those comprising the polymerization of ethylene or the copolymerization of ethylene and a-olefins having from 3 to 10 carbon atoms. Thus, according to another aspect of the present invention there is provided a process for the polymerization of ethylene or the Catalyst B - Inventive Grace-Davison Sylopol 2408 silica was dehydrated in a manner that reduced the total residual volatiles in the silica to 0.9 % by weight. The remaining surface hydroxyl groups in the silica were chemically passified in the following manner. 130 g of the dehydrated Sylopol 2408 silica was slurried in 300 mL of dry, degassed heptane under an inert atmosphere. 156 mL of a 25 weight percent solution of triethyl aluminum (TEAL) in toluene was then added to the silica slurry. An additional 150 mL of heptane was then added. The mixture was swirled by hand and then placed on a rotational agitator, at slow speed, for 3 hours. The solids were then recovered by filtration and washed three times with 200 mL of heptane. The washed solids were then vacuum dried to a residual pressure of 300 millitorr. 118.5 g of the TEAL-passified silica was placed in a 1 L, pear- shaped flask. In a separate 125 mL hypo-vial, 52.8 mL of a 9.7 weight percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)}, known as B-2, and 15.8 mL of 0.25 molar TEAL in toluene were mixed and allowed to sit for 5 minutes. This solution was then added to the TEAL- passified silica in the 1 L flask and mixed slowly on the rotational agitator for 1 hour. 24.5 mL of a 10 weight percent solution of (pentafluorophenylcyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium dichloride in toluene was then added to the 1 L flask which was then mixed on the rotational agitator for an additional 1 hour. This corresponds to a boron:titanium mole ratio of about 1.05:1. 400 mL of heptane was added to the flask, which was then further mixed on the rotational agitator for 1 hour. Solid catalyst was recovered by filtration and washed three times with 250 mL of heptane. The washed catalyst was then dried under vacuum to a residual pressure of 300 millitorr. Metal contents in the supported catalyst were measured to be 0.148 weight percent titanium and 2.6 weight percent aluminum. copolymerization of ethylene and a-olefins having from 3 to 10 carbon atoms, said process performed under polymerization conditions in the present of a supported transition metal catalyst system prepared as hereinbefore described. EXAMPLES Part A - Catalyst Synthesis Catalyst A - Comparative A commercially available silica (Sylopol 2408, from W.R. Grace- Davison) was dehydrated in a manner that reduced the total residual volatiles in the silica to 0.6 % by weight. A supported catalyst, using this dehydrated silica as the support, was prepared in the following manner. 29.00 kg of dehydrated Sylopol 2408 silica was slurried in a minimal amount of toluene under inert atmospheric conditions. 33.67 kg of a 30 weight percent solution of a commercially available methylaluminoxane (MAO purchased from Albemarle) in toluene was metered into the mixture. Upon completion of the MAO addition, the slurry was stirred for an additional 30 minutes. At this point, the slurry was sampled to determine the Al content in the MAO-silica solids and the supernatant liquid. Al content was determined to be 10.9 weight percent in the MAO-silica solid and 539 ppm by weight in the supernatant liquid indicating essentially complete supporting of MAO at this stage. 730.1 g of (pentafluorophenylcyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium dichloride was dissolved in a minimal amount of toluene and added to the MAO-silica slurry. The mixture was then stirred for 1 hour. At this point the slurry concentration was such that the concentration was 25 weight percent solids based on theoretical calculation of the final mass of supported catalyst expected. The slurry was decanted and washed a total of three times with hexane to remove toluene prior to drying. Analysis of the recovered catalyst indicated 11.1 weight percent aluminum, 0.175 weight percent titanium (AI:Ti = 112.6 mole:mole) and 1.3 weight percent residual volatiles. Catalyst C - Comparative Grace-Davison Sylopol 2408 silica was dehydrated in a manner that reduced the total residual volatiles in the silica to 0.9 % by weight. A supported catalyst, using this dehydrated silica as the support, was prepared in the following manner. 144.7 g of dehydrated Sylopol 2408 silica was slurried in a minimal amount of toluene under inert atmospheric conditions. 185 mL of a 30 weight percent solution of Albemarle methylaluminoxane (MAO) in toluene was added into the mixture. Upon completion of the MAO addition, the slurry was stirred for an additional 30 minutes 4.22 g of (1-ethyl-2- pentafluorophenyl-cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium dichloride was dissolved in a minimal amount of toluene and added to the MAO-silica slurry. The mixture was then stirred for 1 hour. The slurry was decanted and washed a total of three times with hexane to remove toluene prior to drying under vacuum to a residual pressure of 300 millitorr. The finished catalyst contained 0.173 percent titanium by weight. Catalyst D Grace-Davison Sylopol 2408 silica was dehydrated in a manner that reduced the total residual volatiles in the silica to 0.9 % by weight. The remaining surface hydroxyl groups in the silica were chemically passified in the following manner. 130 g of the dehydrated Sylopol 2408 silica was slurried in 300 mL of dry, degassed heptane under an inert atmosphere. 156 mL of a 25 weight percent solution of triethyl aluminum (TEAL) in toluene was then added to the silica slurry. An additional 150 mL of heptane was then added. The mixture was swirled by hand and then placed on a rotational agitator, at slow speed, for 3 hours. The solids were then recovered by filtration and washed three times with 200 mL of heptane. The washed solids were then vacuum dried to a residual pressure of 300 millitorr. 94.7 g of the TEAL-passified silica was placed in a 1 L, pear- shaped flask. In a separate 125 mL hypo-vial, 42.3 mL of a 9.7 weight percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)}, known as B-2, and 12.6 mL of 0.25 molar TEAL in toluene were mixed and allowed to sit for 5 minutes. This solution was then added to the TEAL- passified silica in the 1 L flask and mixed slowly on the rotational agitator for 1 hour. 20.6 mL of a 10 weight percent solution of (1-ethyl-2- pentafluorophenyl-cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium dichloride in toluene was then added to the 1 L flask which was then mixed on the rotational agitator for an additional 1 hour. 400 mL of heptane was added to the flask, which was then further mixed on the rotational agitator for 1 hour. Solid catalyst was recovered by filtration and washed three times with 250 mL of heptane. The washed catalyst was then dried under vacuum to a residual pressure of 300 millitorr. The finished catalyst contained 0.148 percent titanium by weight. Catalyst E Grace-Davison Sylopol 2408 silica was dehydrated in a manner that reduced the total residual volatiles in the silica to 0.9 % by weight. The remaining surface hydroxyl groups in the silica were chemically passified in the following manner. 130 g of the dehydrated Sylopol 2408 silica was slurried in 300 mL of dry, degassed heptane under an inert atmosphere. 156 mL of a 25 weight percent solution of triethyl aluminum (TEAL) in toluene was then added to the silica slurry. An additional 150 mL of heptane was then added. The mixture was swirled by hand and then placed on a rotational agitator, at slow speed, for 3 hours. The solids were then recovered by filtration and washed three times with 200 mL of heptane. The washed solids were then vacuum dried to a residual pressure of 300 millitorr. 118.8 g of the TEAL-passified silica was placed in a 1 L, pear- shaped flask. In a separate 125 mL hypo-vial, 52.8 mL of a 9.7 weight percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)}, known as B-2, and 15.8 mL of 0.25 molar TEAL in toluene were mixed and allowed to sit for 5 minutes. This solution was then added to the TEAL- passified silica in the 1 L flask and mixed slowly on the rotational agitator for 1 hour. 27.0 mL of a 10 weight percent solution of (1-n-butyl-2- pentafluorophenyl-cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium dichloride in toluene was then added to the 1 L flask which was then mixed on the rotational agitator for an additional 1 hour. 400 mL of heptane was added to the flask, which was then further mixed on the rotational agitator for 1 hour. Solid catalyst was recovered by filtration and washed three times with 250 mL of heptane. The washed catalyst was then dried under vacuum to a residual pressure of 300 millitorr. The finished catalyst contained 0.133 percent titanium and 2.5 percent aluminum by weight. Catalysts F, G, and H Grace-Davison Sylopol 948 silica was dehydrated at 250°C under a nitrogen atmosphere for 5 hours, prior to use in the preparation of the TEAL-passified silica described in the following section, a) TEAL-passified Silica (SiO2/TEAL) Add 650 mL of dry, degassed heptane to a 1 L, pear-shaped flask, followed by 11.25 of a 0.29 wt % solution of Stadis® 425 (Octel Starrion L.L.C.) in heptane and 150 g of calcined Sylopol 948 silica. The flask was placed on the rotating arm of a rotary evaporator and turned slowly for 15 minutes. 100 mL of a 25 wt % TEAL in hexane solution was added to the flask and then swirled by hand (Note: there is some heat evolution). 75 mL of 25 wt % TEAL in hexane was then added. The flask was then placed on the rotating arm of a rotary evaporator and turned slowly for 1 hour. The slurry was filtered. The filter cake was transferred back to the flask, reslurried in 350 mL of heptane and rotated for an additional 30 minutes. The slurry was filtered. The filter cake was transferred back to the flask, reslurried in 350 mL of heptane and rotated for an additional 30 minutes. The slurry was filtered a third time. The filter cake was transferred back to the flask, reslurried in 350 mL of heptane along with 11.25 mL of the 0.29 wt % solution of Stados® 425 in heptane. The flask was placed on the rotating arm of a rotary evaporator and turned slowly for 15 minutes. The solvent was then removed under vacuum while heating to 60°C to reach a final vacuum of 300 millitorr. b) Supported Catalyst Preparation Supported catalysts F, G and H were prepared according the following recipe and differ only in the choice and amount of catalyst precursor molecule. Working in a glovebox under inert atmospheric conditions, 1.43 mL of a 9.58 weight percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)} and 0.42 mL of 0.25 molar TEAL in toluene were mixed in a 100 mL round-bottomed flask and allowed to sit for 5 minutes. 1.61 g of SiO2/TEAL was then added and the mixture was shaken on a Lab-Line Mistral Multi-Mixer at high speed for 1 hour. The appropriate amount of a solution of the catalyst precursor molecule in heptane was premixed with 0.3 mL of dry, degassed hexene in a hypo-vial and swirled on the Multi-Mixer gently for 15 minutes. For Catalyst F, 0.85 mL of 10 wt % (dimethyl)(1-n-butyl-2-pentafluorophenyl-cyclopentadienyl)(tri- tertiarybutylphosphinimido)titanium in heptane was premixed with the 0.3 mL of hexene. For Catalyst G, 1.05 mL of 8 wt % (dimethyl)(2-pentafluorophenyl-indenyl)(tri- tertiarybutylphosphinimido)titanium in heptane was premixed with the 0.3 mL of heptane. For Catalyst H, 0.53 mL of 10 wt % (dimethyl)(cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium in heptane was premixed with the 0.3 mL of hexene. The molecule plus hexene solution was then added to the flask containing the support plus activator material. The flask was then shaken for 1 hour. 0.20 mL of a 2g/L solution of Stadis® 425 (available from Octel Starrion L.L.C.) in heptane was then added to the mixture followed by an additional 15 minutes of mixing. The flask was then placed under vacuum and dried to a residual pressure of 300 millitorr. Finished catalyst F contained 0.202 percent titanium by weight. Finished catalyst G contained 0.212 percent titanium by weight. Finished catalyst H contained 0.320 percent titanium by weight. Part B - Ethylene Homopolvmerization Ethylene homopolymerization experiments were conducted on a 2 L, stirred, autoclave reactor in gas phase operation. The polymerizations were run at 85°C for 60 minutes under an ethylene pressure of 200 psig. During reactor conditioning and setup, 0.4 mL of a 25 weight percent solution of tri-isobutylaluminum (TiBAL) was used as an impurity scavenger to assist with purification of reactor internals and the seedbed (which was 130 grams of granular high density polyethylene "HDPE"). Prior to initiation of polymerization, 25 - 30 mg of catalyst was loaded into an injection tube under anaerobic conditions in a glovebox and was then connected to the reactor. A portion of the ethylene gas used to create the 200 psig pressure was used to push the catalyst into the reactor to initiate polymerization. Throughout the polymerization, ethylene was allowed to flow to the reactor through a mass flow meter to maintain a constant pressure of 200 psig. Measurement of this ethylene flow rate over time provided a measure of polymerization rate as a function of time. Ethylene homopolymerization details are provided in Table 1. Part C - Copolvmerization Ethylene-hexene copolymerization experiments were conducted on a 2 L, stirred, autoclave reactor in gas phase operation. Copolymerizations were run at 85°C for 60 minutes with a total operating pressure of 200 psig. Gas phase compositions for ethylene and hexene were controlled via closed-loop process control to values of 40.0 and 0.20 mole percent, respectively. Hydrogen was metered into the reactor in a molar feed ratio of 0.0014 relative to ethylene feed during polymerization. Nitrogen constituted the remainder of the gas phase mixture (approximately 59.2 mole %). During reactor conditioning and setup, 0.4 mL of a 25 weight percent solution of tri-isobutylaluminum (TiBAL) was used as an impurity scavenger to assist with purification of reactor internals and the 130 g HDPE seedbed. Catalysts (see Table 2) were loaded into an injection tube under anaerobic conditions in a glovebox and was then connected to the reactor. A portion of the nitrogen used to make up the reactor gas composition was used to push the catalyst into the reactor at the start of polymerization. The reactor was vented at a controlled rate throughout the polymerization, which in combination with gas consumption due to polymerization allowed for maintenance of controlled gas phase composition through the copolymerization reaction. The details of the ethylene-hexene copolymerizations performed in the presence of added hydrogen are given in Table 2. Physical characterization data for the polymers produced in Examples 6 to 10 are also presented in Table 2. The data in Table 2 indicate that the inventive catalysts provide good comonomer incorporation in ethylene-hexene copolymerizations. A second set of ethylene-hexene copolymerization experiments were run under the following conditions. Copolymerizations were run at 70°C for 60 minutes with a total operating pressure of 300 psig. Gas phase compositions for ethylene and hexene were controlled via closed-loop process control to values of 50.0 and 0.14 mole percent, respectively. Hydrogen was metered into the reactor in a molar feed ratio of 0.00168 relative to ethylene feed during polymerization. Nitrogen constituted the remainder of the gas phase mixture (approximately 49.2 mole %). During reactor conditioning and setup, 0.4 mL of a 25 weight percent solution of tri-isobutylaluminum (TiBAL) was used as an impurity scavenger to assist with purification of reactor internals and the 100 g HDPE seedbed. Catalysts (see Table 3) were loaded into an injection tube under anaerobic conditions in a glovebox and was then connected to the reactor. A portion of the nitrogen used to make up the reactor gas composition was used to push the catalyst into the reactor at the start of polymerization. The reactor was vented at a controlled rate throughout the polymerization, which in combination with gas consumption due to polymerization allowed for maintenance of controlled gas phase composition through the copolymerization reaction. The details of the ethylene-hexene copolymerizations performed in the presence of added hydrogen are given in Table 3. Use of the statistical t-test comparing the productivity of Catalyst H to either Catalyst F or Catalyst G indicates that Catalyst F and Catalyst G give productivities approximately double that seen for Catalyst H with a greater than 99 percent confidence level. INDUSTRIAL APPLICABILITY A supported catalyst for olefin polymerization comprising a specific type of activator, a specific organometallic catalyst species and a support which is preferably a metal oxide. The supported catalyst is especially suitable for slurry or gas phase polymerizations and exhibits very high activity in gas phase polymerizations. The polyethylene produced with this catalyst is suitable for the production of a wide variety of goods, ranging from flexible plastic films to rigid plastic containers. WE CLAIM: 1. A supported catalyst comprising: (a) (1) a support material; (a) (2) an organometal or metalloid compound wherein the metal or metalloid is selected from the group consisting of magnesium, zinc, boron, aluminium, germanium, tin, lead, and mixtures thereof; and (b) an activator compound comprising: (b)(1) a cation which is capable of reacting with a transition metal metallocene compound to form a transition metal complex which is catalytically active for the polymerization of alpha-olefins; (b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one substituent comprising a moiety having an active hydrogen; and (c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the formula: wherein M is a group 4 metal; * Cp is a substituted eta-5 bonded cyclopentadienyl ligand which contains from 7 to 30 carbon atoms; PI is a phosphinimine ligand; L is a leaving group ligand; and n is 1 or 2, depending upon the valence of m, with the further provisos that: a) said catalyst contains from 1 to 2,000 mu.mol of activator compound per gram of support material; and b) Cp is selected from the group consisting of 2-pen-tafluorophenyl cyclopentadienyl, tri- butyl-2- pentafluorophenyl cyclopentadienyl and 2-pentafluorophenyl indenyl. 2. The supported catalyst of claim 1 wherein M is Ti. ABSTRACT Title: SUPPORTED POLYMERIZATION CATALYSTS A supported catalyst comprising: (a) (1) a support material; (a) (2) an organometal or metalloid compound wherein the metal or metalloid is selected from the group consisting of magnesium, zinc, boron, aluminum, germanium, tin, lead, and mixtures thereof; and (b) an activator compound comprising: (b)(1) a cation which is capable of reacting with a transitin metal metallocene compound to form a transition metal complex which is catalytically active for the polymerization of alpha-olefins; (b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one substituent comprising a moiety having an active hydrogen; and (c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the formula: wherein M is a group 4 metal; Cp is a substituted eta-5 bonded cyclopentadienyl ligand which contains from 7 to 30 carbon atoms; PI is a phosphinimine ligand; L is a leaving group ligand; and n is 1 or 2, depending upon the valence of m, with the further provisos that: c) said catalyst contains from 1 to 2,000 mu.mol of activator compound per gram of support material; and d) *Cp is selected from the group consisting of 2-pen-tafluorophenyl cyclopentadienyl, tri- butyl-2- pentafluorophenyl cyclopentadienyl and 2-pentafluorophenyl indenyl.

Full Text

SUPPORTED POLYMERIZATION CATALYSTS
TECHNICAL FIELD
The present invention relates to supported catalysts suitable for the
polymerization of olefins and in particular to supported metallocene
catalysts providing advantages for operation in gas phase and slurry
processes.
BACKGROUND ART
In recent years there have been many advances in the production
of polyolefin homopolymers and copolymers due to the introduction of
metallocene catalysts.
Metallocene catalysts offer the advantage of generally a higher
activity than traditional Ziegler catalysts and are usually described as
catalysts which are single site in nature.
There have been developed several different families of
metallocene complexes. In earlier years catalysts based on bis
(cyclopentadienyl) metal complexes were developed, examples of which
may be found in EP 129 368 or EP 206 794. More recently complexes
having a single or mono cyclopentadienyl ring have been developed.
Certain of such monocyclopentadienyl complexes have been referred to
as constrained geometry complexes and examples of these complexes
may be found in EP 416 815 or EP 420 436. In both of these complexes
the metal atom e.g. zirconium is the highest oxidation state.
Other complexes however have been developed in which the metal
atom may be in a reduced oxidation state. Examples of both the bis
(cyclopentadienyl) and mono (cyclopentadienyl) complexes have been
described in WO 96/04290 and WO 95/00526 respectively.
The above metallocene complexes are utilized for polymerization in
the presence of a cocatalyst or activator. Typically activators are
aluminoxanes, in particular methyl aluminoxane or compounds based on
boron compounds. Examples of the latter are borates such as trialkyl-
substituted ammonium tetraphenyl or tetrafluorophenyl borates. Catalyst

systems incorporating such borate activators are described in EP 516 479,
EP 418 044 and EP 551 277.
The above metallocene complexes may be used for the
polymerization of olefins in solution, slurry or gas phase. When used in
the gas phase the metallocene complex and/or the activator are suitably
supported. Typical supports include inorganic oxides (e.g. silica or
alumina) or polymeric supports may alternatively be used.
Examples of the preparation of supported metallocene catalysts for
the polymerization of olefins may be found in WO 94/26793, WO
95/07939, WO 96/00245, WO 96/04318, WO 97/02297 and EP 642 536.
WO 98/27119 describes supported catalyst components comprising
ionic compounds comprising a cation and an anion in which the anion
contains at least one substituent comprising a moiety having an active
hydrogen. In this disclosure supported metallocene catalysts are
exemplified in which the catalyst is prepared by treating the
aforementioned ionic compound with a trialkylaluminum compound
followed by subsequent treatment with the support and the metallocene.
WO 98/27119 also describes a method for activating a substantially
inactive catalyst precursor comprising (a) an ionic compound comprising a
cation and an anion containing at least one substituent comprising a
moiety having an active hydrogen; (b) a transition metal compound; and
optionally (c) a support by treatment with an organometallic compound
thereby forming an active catalyst.
Various methods have been utilized to prepare supported catalysts
of this type.
For example, WO 98/27119 describes several methods of preparing
the supported catalysts disclosed therein in which the support is
impregnated with the ionic compound. The volume of the ionic compound
may correspond from 20 volume percent to greater than 200 volume
percent of the total pore volume of the support. In a preferred preparative
route the volume of the solution of the ionic compound does not exceed

substantially, and is preferably equal to, the total pore volume of the
support.
Such methods of preparation may be referred to as incipient
precipitation or incipient wetness techniques.
More recently WO 02/06357 describes an improved incipient
wetness technique for the preparation of a supported metallocene catalyst
system in which the support is impregnated with an ionic compound and
the metallocene complex followed by treatment with an organometallic
compound.
The preferred metal with respect to the organometallic compound is
aluminum and the preferred metal for the ionic activator is boron whereby
the molar ratio of Al/B is in the range of 0.1 to 2.0, and is preferably in the
range of 0.1 to 0.8, and most preferably in the range of 0.3 to 0.6.
The "ionic activators" described above are highly desirable for slurry
and gas phase olefin polymerizations especially for the preparation of
catalysts which are not as prone to cause reactor fouling as similar
catalysts prepared with aluminoxanes. One challenge that remains is to
increase the activity/productivity of catalysts that incorporate these
activators. We have discovered that certain catalyst molecules having
cyclopentadienyl and phosphinimine ligands exhibit excellent activity when
the cyclopentadienyl ligand is substituted. The level of substitution should
include at least 2 carbon atoms. A preferred maximum level of substitution
is 25 carbon atoms (on the 5 carbon atom ring of the cyclopentadienyl
ligand) due to steric considerations.
DISCLOSURE OF INVENTION
The present invention provides a supported catalyst comprising of:
(a)(1) a support material;
(a)(2) an organometal or metalloid compound wherein the
metal or metalloid is selected from the group consisting of magnesium,
zinc, boron, aluminum, germanium, tin, lead, and mixtures thereof; and
(b) an activator compound comprising:

(b)(1) a cation which is capable of reacting with a
transition metal metallocene compound to form a transition metal
complex which is catalytically active for the polymerization of alpha-
olefins;
(b)(2) a compatible anion having up to 100
nonhydrogen atoms and containing at least one substituent
comprising a moiety having an active hydrogen; and
(c) phosphinimine/substituted cyclopentadienyl organometallic
complex according to the formula:

wherein M is a group 4 metal; *Cp is a eta-5 bonded cyclopentadienyl
ligand; PI is a phosphinimine ligand having at least one hydrocarbyl
substituent containing from one to 20 carbon atoms; L is a leaving group
ligand; and n is 1 or 2, depending upon the valence of m.
The use of the substituted cyclopentadienyl ligand with the defined
supported activator provides an exceptional catalyst.
BEST MODE FOR CARRYING OUT THE INVENTION
Detailed descriptions of essential catalyst components (namely (i)
the support; (ii) the catalyst molecule; and (iii) the organometal/metalloid.
Particulate Metal Oxide Support
The catalyst of this invention must be prepared with a particulate
metal oxide support.
The use of metal oxide supports in the preparation of olefin
polymerization catalysts is known to those skilled in the art. An exemplary
list of suitable metal oxides includes oxides of aluminum, silicon,
zirconium, zinc and titanium. Alumina, silica and silica-alumina are metal
oxides which are well known for use in olefin polymerization catalysts and
are preferred for reasons of cost and convenience. Silica is particularly
preferred.

It is preferred that the metal oxide have a particle size of from about
1 to about 200 microns. It is especially preferred that the particle size be
between about 30 and 100 microns if the catalyst is to be used in a gas
phase or slurry polymerization process and that a smaller particle size
(less than 10 microns) be used if the catalyst is used in a solution
polymerization.
Conventional porous metal oxides, which have comparatively high
surface areas (greater than 1 m2/g, particularly greater than 100 m2/g,
more particularly greater than 200 m2/g), are preferred to non-porous
metal oxides.
The support material may be subjected to a heat treatment and/or
chemical treatment to reduce the water content or the hydroxyl content of
the support material.
Typically chemical dehydration agents are reactive metal hydrides,
aluminum alkyls and halides. Prior to its use the support material may be
subjected to treatment at 100°C to 1000°C and preferably at 200 to 850°C
in an inert atmosphere under reduced pressure.
The support material may be further combined with an
organoaluminum compound and most preferably a trialkylaluminum
compound in a dilute solvent.
The support material is preferably pretreated with the
trialkylaluminum compound at a temperature of 20°C to 150°C and
preferably at 20°C to 100°C.
The molar ration of transition metal in the catalyst compound (which
transition metal is preferably titanium or zirconium) to ionic activator
employed in the method of the present invention may be in the range
1:10000 to 100:1. A preferred range is from 1:5000 to 10:1 and most
preferred from 1:10 to 10:1.
2. CATALYST MOLECULE
The catalyst molecule of the present invention is a phosphinimine
complex of a group 4 transition metal having at least one phosphinimine

ligand (as defined below), at least one leaving group (as defined below)
and at least one substituted cyclopentadienyl ligand..
These catalyst molecules are represented by the formula:

wherein PI is a phosphinimine ligand; M is a group 4 transition metal; L is
an activatable ligand; n is one or two, depending upon the valences of M
and L; and *Cp is a substituted cyclopentadienyl ligand which is eta-5
bonded with the group 4 transition metal and which contains from 7 to 30
carbon atoms.
2.1 *Cp Ligand
The *Cp ligand is a substituted cyclopentadienyl ligand which
contains a total of from 7 to 30 carbon atoms.
The use of substituents on such cyclic ligands is well known and is
described, for example, in U.S. Patent 5,324,800 (Welborn). An
exemplary list of substituents for such Cp ligands includes C1-20
hydrocarbyl groups; substituted C1-20 hydrocarbyl groups wherein one or
more hydrogen atoms is replaced by a halogen; an amido group, a
phosphido group, or an alkoxy group. The substituent may form a bridge
with the phosphinimine ligand. The substituents may be bonded to each
other (as in, fro example, an indenyl ligand). As shown in the examples,
fluoro-substituted Cp ligands are preferred.
A cyclopentadienyl ligand contains 5 carbon atoms in the ring
structure. The substituted cyclopentadienyl ligand used in this invention
must contain at least 7 carbon atoms, i.e. in addition to the 5 carbon atoms
of the cyclopentadienyl ligand, at least 2 extra carbon atoms are required.
2.2 Phosphinimine Ligand
The catalyst component of this invention must contain a
phosphinimine ligand, which is covalently bonded to the metal. This ligand
is defined by the formula:

wherein each R" is independently selected from the group consisting of a
hydrogen atom, a halogen atom, C1-20 hydrocarbyl radicals which are
unsubstituted by or further substituted by a halogen atom, a C1-8 alkoxy
radical, a C6-10 aryl or aryloxy radical, an amido radical, a silyl radical of the
formula:

wherein each R2 is independently selected from the group consisting of
hydrogen, C1-8 alkyl or alkoxy radical, C6-10 aryl or aryloxy radicals, and a
germanyl radical of the formula:

wherein R2 is as defined above.
The preferred phosphinimines are those in which each R" is a
hydrocarbyl radical. A particularly preferred phosphinimine is tri-(tertiary
butyl) phosphinimine (i.e. where each R" is a tertiary butyl group).
2.3 Activatable Ligand
The term "activatable ligand" refers to a ligand which may be
activated by a cocatalyst (also known as an "activator" to facilitate olefin
polymerization. Exemplary activatable ligands are independently selected
from the group consisting of a hydrogen atom, a halogen atom, a C1-10
hydrocarbyl radical, a C1-20 alkoxy radical, a C5-10 aryl oxide radical; each
of which said hydrocarbyl, alkoxy, and aryl oxide radicals may be
unsubstituted by or further substituted by a halogen atom, a C1-8 alkyl
radical, a C1-8 alkoxy radical, a C6-10 aryl or aryl oxy radical, an amido
radical which is unsubstituted or substituted by up to two C1-8 alkyl
radicals; a phosphido radical which is unsubstituted or substituted by up to
two C1-8 alkyl radicals.

3. ORGANOMETAL/METALLOID AND IONIC ACTIVATOR
The support material is treated with the organometal compound.
Suitable organometal compounds are those comprising metals of Groups
2-13, germanium, tin, and lead, and at least two substituents selected from
hydride, hydrocarbyl radicals, trihydrocarbyl silyl radicals, and
trihydrocarbyl germyl radicals. Additional substituents preferably comprise
one or more substituents selected from hydride, hydrocarbyl radicals,
trihydrocarbyl substituted silyl radicals, trihydrocarbyl substituted germyl
radicals, and hydrocarbyl-, trihydrocarbyl silyl- or trihydrocarbyl germyl-
substituted metalloid radicals.
The recitation "metalloid", as used herein, includes non-metals such
as boron, phosphorus and the like which exhibit semi-metallic
characteristics.
Examples of such organometal compounds include
organomagnesium, organozinc, organoboron, organoaluminum,
organogermanium, organotin, and organolead compounds, and mixtures
thereof. Further suitable organometal compounds are alumoxanes.
Preferred examples are alumoxanes and compounds represented by the
following formulae: MgR12, ZnR12, BR1xR2y, AIR1xR2y, wherein R1
independently each occurrence is hydride, a hydrocarbyl radical, a
trihydrocarbyl silyl radical, a trihydrocarbyl germyl radical, or a
trihydrocarbyl-, trihydrocarbyl silyl-, or trihydrocarbyl germyl-substituted
metalloid radical, R2 independently is the same as R1, x is 2 or 3, y is 0 or
1 and the sum of x and y is 3, and mixtures thereof. Examples of suitable
hydrocarbyl moieties are those having from 1 to 20 carbon atoms in the
hydrocarbyl portion thereof, such as alkyl, aryl, alkaryl, or aralkyl.
Preferred radicals include methyl, ethyl, n- or i-propyl, n-, s- or t-butyl,
phenyl, and benzyl. Preferably, the aluminum component is selected from
the group consisting of alumoxane and aluminum compounds of the
formula AIR1X wherein R1 in each occurrence independently is hydride or a
hydrocarbyl radical having from 1 to 20 carbon atoms, and x is 3. Suitable
trihydrocarbyl aluminum compounds are trialkyl or triaryl aluminum

compounds wherein each alkyl or aryl group has from 1 to 10 carbon
atoms, or mixtures thereof, and preferably trialkyl aluminum compounds
such as trimethyl, triethyl, tri-isobutyl aluminum.
Alumoxanes (also referred to as aluminoxanes) are oligomeric or
polymeric aluminum oxy compounds containing chains of alternating
aluminum and oxygen atoms, whereby the aluminum carries a substituent,
preferably an alkyl group. The structure of alumoxane is believed to be
represented by the following general formulae (-AI(R)-O)m, for a cyclic
alumoxane, and R2 AI--O(--AI(R)--O)m--AIR2, for a linear compound,
wherein R independently in each occurrence is a C1-C10 hydrocarbyl,
preferably alkyl, or halide and m is an integer ranging from 1 to about 50,
preferably at least about 4. Alumoxanes are typically the reaction products
of water and an aluminum alkyl, which in addition to an alkyl group may
contain halide or alkoxide groups. Reacting several different aluminum
alkyl compounds, such as, for example, trimethyl aluminum and tri-isobutyl
aluminum, with water yields so-called modified or mixed alumoxanes.
Preferred alumoxanes are methylalumoxane and methylalumoxane
modified with minor amounts of other lower alkyl groups such as isobutyl.
Alumoxanes generally contain minor to substantial amounts of starting
aluminum alkyl compound.
The way in which the alumoxane is prepared is not critical. When
prepared by the reaction between water and aluminum alkyl, the water
may be combined with the aluminum alkyl in various forms, such as liquid,
vapor, or solid, for example in the form of crystallization water. Particular
techniques for the preparation of alumoxane type compounds by
contacting an aluminum alkyl compound with an inorganic salt containing
water of crystallization are disclosed in U.S. Patent 4,542,199. In a
particular preferred embodiment an aluminum alkyl compound is contacted
with a regeneratable water-containing substance such as hydrated
alumina, silica or other substance. This is disclosed in European Patent
Application No. 338,044.

The supported catalyst component and supported catalyst of the
present invention generally comprise a support material combined or
treated with the organometal compound, preferably an aluminum
component, and containing at least 0.1 micromol of organometal
compound per g of support material, typically at least 5 micromole per g
support material, advantageously at least 0.5 weight percent of the metal,
preferably aluminum, expressed in gram of metal, preferably aluminum,
atoms per g of support material. Preferably, the amount of metal,
advantageously aluminum, is at least 2 weight percent, and generally not
more than 40 weight percent, and more preferably not more than 30
weight percent. At too high amounts of metal, preferably aluminum, the
supported catalyst becomes expensive. At too low amounts the catalyst
efficiency goes down to drop below acceptable levels.
The supported catalyst component and supported catalyst of the
present invention preferably contain a treated support material (a)
comprising a support material and an alumoxane wherein not more than
about 10 percent aluminum present in the treated support material is
extractable in a one hour extraction with toluene of 90°C using about 10
ml_ toluene per gram of pretreated support material. More preferably, not
more than about 9 percent aluminum present in the supported catalyst
component is extractable, and most preferably not more than about 8
percent. This is especially advantageous when the supported catalyst
component or catalyst prepared therefrom is used in a polymerization
process where a diluent or solvent is used which may extract non-fixed
alumoxane from the support material. It has been found that when the
amount of extractables is below the levels given above, the amount of
alumoxane that can diffuse into the polymerization solvent or diluent, if
used, is so low that no appreciable amount of polymer will be formed in the
diluent, as compared to polymer formed on the support material. If too
much polymer is formed in the diluent the polymer bulk density will
decrease below acceptable levels and reactor fouling problems may occur.

The toluene extraction test is carried out as follows: About 1 g of
supported catalyst component or supported catalyst, with a known
aluminum content, is added to 10 mL toluene and the mixture is then
heated to 90°C under an inert atmosphere. The suspension is stirred well
at this temperature for 1 hour. Then the suspension is filtered applying
reduced pressure to assist in the filtration step. The solids are washed
twice with about 3 to 5 mL toluene of 90°C per gram of solids. The solids
are then dried at 120°C for 1 hour, and subsequently the aluminum
content of the solids is measured. The difference between the initial
aluminum content and the aluminum content after the extraction divided by
the initial aluminum content and multiplied by 100%, gives the amount of
extractable aluminum.
The aluminum content can be determined by slurrying about 0.5 g
of supported catalyst component or supported catalyst in 10 mL hexane.
More specifically, preferred activator compounds contain a
compatible anion having up to 100, and preferably up to 50 non-hydrogen
atoms and having at least one substituent comprising an active hydrogen
moiety. Preferred substituents comprising an active hydrogen moiety
correspond to the formula:

wherein G is a polyvalent hydrocarbon radical, T is O, S, NR, or PR,
wherein R is a hydrocarbyl radical, a trihydrocarbyl silyl radical, a
trihydrocarbyl germyl radical, or hydrogen, H is hydrogen, q is 0 or 1, and
preferably 1, and r is an integer from 1 to 3, preferably 1. Polyvalent
hydrocarbon radical G has r+1 valencies, one valency being with a metal
or metalloid of the Groups 5-15 of the Periodic Table of the Elements in
the compatible anion, the other valency or valencies of G being attached
to r groups T--H. Preferred examples of G include divalent hydrocarbon
radicals such as: alkylene, arylene, aralkylene, or alkarylene radicals
containing from 1 to 20 carbon atoms, more preferably from 2 to 12 carbon
atoms. Suitable examples of G include phenylene, biphenylene,
naphthylene, methylene, ethylene, 1,3-propylene, 1,4-butylene,

phenylmethylene (--C6H4--CH2--). The polyvalent hydrocarbyl portion G
may be further substituted with radicals that do not interfere with the
coupling function of the active hydrogen moiety. Preferred examples of
such noninterfering substituents are alkyl, aryl, alkyl- or aryl-substituted
silyl and germyl radicals, and fluoro substituents.
The group T--H in the previous formula thus may be an -OH, --SH,
-NRH, or --PRH group, wherein R preferably is a C1-18, preferably a C1-10
hydrocarbyl radical or hydrogen, and H is hydrogen. Preferred R groups
are alkyls, cycloalkyls, aryls, arylalkyls, or alkylaryls of 1 to 18 carbon
atoms, more preferably those of 1 to 12 carbon atoms. The -OH, --SH,
-NRH, or --PRH groups may be part of a larger functionality such as, for
example, C(O)-OH, C(S)~SH, C(O)~NRH, and C(O)~PRH. Most
preferably, the group T--H is a hydroxy group, -OH, or an amino group,
-NRH.
Very preferred substituents Gq(T-H)r comprising an active
hydrogen moiety include hydroxy- and amino-substituted aryl, aralkyl,
alkaryl or alkyl groups, and most preferred are the hydroxyphenyls,
especially the 3- and 4-hydroxyphenyl groups, hydroxytolyls, hydroxy
benzyls (hydroxymethylphenyl), hydroxybiphenyls, hydroxynaphthyls,
hydroxycyclohexyls, hydroxymethyls, and hydroxypropyls, and the
corresponding amino-substituted groups, especially those substituted with
-NRH wherein R is an alkyl or aryl radical having from 1 to 10 carbon
atoms, such as for example methyl, ethyl, propyl, i-propyl, n-, i-, or t-butyl,
pentyl, hexyl, heptyl, octyl, nonyl, and decyl, phenyl, benzyl, tolyl, xylyl,
naphthyl, and biphenyl.
The compatible anion containing the substituent which contains an
active hydrogen moiety, may further comprise a single Group 5-15
element or a plurality of Group 5-15 elements, but is preferably a single
coordination complex comprising a charge-bearing metal or metalloid core,
which anion is bulky. A compatible anion specifically refers to an anion
which when functioning as a charge balancing anion in the catalyst system
of this invention, does not transfer an anionic substituent or fragment

thereof to the transition metal cation thereby forming a neutral transition
metal compound and a neutral metal by-product. "Compatible anions" are
anions which are not degraded to neutrality when the initially formed
complex decomposes and are non-interfering with desired subsequent
polymerizations. Preferred anions are those containing a single
coordination complex comprising a charge-bearing metal or metalloid core
carrying a substituent containing an active hydrogen moiety which anion is
relatively large (bulky), capable of stabilizing the active catalyst species
(the transition metal cation) which is formed when the activator compound
and transition metal compound are combined and said anion will be
sufficiently labile to be displaced by olefinic, diolefinic and acetylenically
unsaturated compounds or other neutral Lewis bases such as ethers,
nitrites and the like. Suitable metals for the anions of activator compounds
include, but are not limited to, aluminum, gold, platinum and the like.
Suitable metalloids include, but are not limited to, boron, phosphorus,
silicon and the like. Activator compounds which contain anions comprising
a coordination complex containing a single boron atom and a substituent
comprising an active hydrogen moiety are preferred.
Preferably, compatible anions containing a substituent comprising
an active hydrogen moiety may be represented by the following general
Formula (I):

wherein M' is a metal or metalloid selected from Groups 5-15 of the
Periodic Table of the Elements; Q independently in each occurrence is
selected from the group consisting of hydride, dihydrocarbylamido,
preferably dialkylamido, halide, hydrocarbyloxide, preferably alkoxide and
aryloxide, hydrocarbyl, and substituted-hydrocarbyl radicals, including
halo-substituted hydrocarbyl radicals, and hydrocarbyl- and
halohydrocarbyl-substituted organo-metalloid radicals, the hydrocarbyl
portion having from 1 to 20 carbons with the proviso that in not more than
one occurrence is Q halide; G is a polyvalent, having r+1 valencies and
preferably divalent hydrocarbon radical bonded to M' and T; T is O, S, NR,

or PR, wherein R is a hydrocarbon radicals a trihydrocarbyl silyl radical, a
trihydrocarbyl germyl radical, or hydrogen; m is an integer from 1 to 7,
preferably 3; n is an integer from 0 to 7, preferably 3; q is an integer 0 or 1,
preferably 1; r is an integer from 1 to 3, preferably 1; z is an integer from 1
to 8, preferably 1; d is an integer from 1 to 7, preferably 1; and n+z-m=d.
Preferred boron-containing anions which are particularly useful in
this invention may be represented by the following general Formula (II):

wherein B is boron in a valence state of 3; z' is an integer from 1-4,
preferably 1; d is 1; and Q, G, T, H, q, and r are as defined for Formula (I).
Preferably, z' is 1, q is 1, and r is 1.
Illustrative, but not limiting, examples of anions of activator
compounds to be used in the present invention are boron-containing
anions such as triphenyl(hydroxyphenyl)borate, diphenyl-
di(hydroxyphenyl)borate, triphenyl(2,4-dihydroxyphenyl)borate, tri(p-
tolyl)(hydroxyphenyl)borate, tris-
(pentafluorophenyl)(hydroxyphenyl)borate, tris-(2,4-
dimethylphenyl)(hydroxyphenyl)borate, tris-(3,5-
dimethylphenyl)(hydroxyphenyl)borate, tris-(3,5-di-
trifluoromethylphenyl)(hydroxyphenyl)borate, tris(pentafluorophenyl)(2-
hydroxyethyl)borate, tris(pentafluorophenyl)(4-hydroxybutyl)borate,
tris(pentafluorophenyl)(4-hydroxycyclohexyl)borate,
tris(pentafluorophenyl)(4-(4'-hydroxyphenyl)phenyl)borate,
tris(pentafluorophenyl)(6hydroxy-2-naphthyl)borate, and the like. A highly
preferred activator complex is tris(pentafluorophenyl)(4-
hydroxyphenyl)borate. Other preferred anions of activator compounds are
those above mentioned borates wherein the hydroxy functionality is
replaced by an amino NHR functionality wherein R preferably is methyl,
ethyl, or t-butyl.
The cationic portion b.1) of the activator compound to be used in
association with the compatible anion b.2) can be any cation which is
capable of reacting with the transition metal compound to form a

catalytically active transition metal complex, especially a cationic transition
metal complex. The cations b.1) and the anions b.2) are used in such
ratios as to give a neutral activator compound. Preferably the cation is
selected from the group consisting of Bronsted acidic cations, carbonium
cations, silylium cations, and cationic oxidizing agents.
Bronsted acidic cations may be represented by the following
general formula:

wherein L is a neutral Lewis base, preferably a nitrogen, phosphorus, or
sulfur containing Lewis base; and (L-H)+ is a Bronsted acid. The
Bronsted acidic cations are believed to react with the transition metal
compound by transfer of a proton of said cation, which proton combines
with one of the ligands on the transition metal compound to release a
neutral compound.
Illustrative, but not limiting, examples of Bronsted acidic cations of
activator compounds to be used in the present invention are trialkyl-
substituted ammonium cations such as triethylammonium,
tripropylammonium, tri(n-butyl)ammonium, trimethylammonium,
tributylammonium, and tri(n-octyl)ammonium. Also suitable are N,N-
dialkyl anilinium cations such as N,N-dimethylanilinium, N,N-
diethylanilinium, N,N-2,4,6-pentamethylanilinium, N,N-
dimethylbenzylammonium and the like; dialkylammonium cations such as
di-(i-propyl)ammonium, dicyclohexylammonium and the like; and
triarylphosphonium cations such as triphenylphosphonium,
tri(methylphenyl)phosphonium, tri(dimethylphenyl)phosphonium,
dimethylsulphonium, diethylsulphonium, and diphenylsulphonium.
Particularly suitable are those cations having longer alkyl chains
such as dihexydecylmethylammonium, dioctadecylmethylammonium,
ditetradecylmethylammonium, bis (hydrogenated tallow alkyl)
methylammonium and similar.
Particular preferred activators of this type are alkylammonium tris
(pentaflurorphenyl) 4-(hydroxyphenyl) borates. A particularly preferred

activator is bis (hydrogenated tallow alkyl) methyl ammonium tris
(pentafluorophenyl) (4-hydroxyphenyl) borate.
A second type of suitable cations corresponds to the formula: C+
wherein C+ is a stable carbonium or silylium ion containing up to 30 non-
hydrogen atoms, the cation being capable of reacting with a substituent of
the transition metal compound and converting it into a catalytically active
transition metal complex, especially a cationic transition metal complex.
Suitable examples of cations include tropyllium, triphenylmethylium,
benzene(diazonium). Silylium salts have been previously generically
disclosed in J. Chem. Soc. Chem. Comm., 1993, 383-384, as well as
Lambert, J. B., et al., Organometallics, 1994, 13, 2430-2443. Preferred
silylium cations are triethylsilylium, and trimethylsilylium and ether
substituted adducts thereof.
Another suitable type of cation comprises a cationic oxidizing agent
represented by the formula:

wherein Oxe+ is a cationic oxidizing agent having a charge of e+, and e is
an integer from 1 to 3.
Examples of cationic oxidizing agents include: ferrocenium,
hydrocarbyl-substituted ferrocenium, Ag+, and Pb2+.
The quantity of activator compound in the supported catalyst
component and the supported catalyst is not critical, but typically ranges
from 0.1, preferably from 1 to 2,000 micromoles of activator compound per
gram of treated support material. Preferably, the supported catalyst or
component contains from 10 to 1,000 micromoles of activator compound
per gram of treated support material.
The supported catalyst component of the present invention as such
or slurried in a diluent can be stored or shipped under inert conditions, or
can be used to generate the supported catalyst of the present invention.
With respect to this type of activator, a particularly preferred
compound is the reaction product of an alkylammonium tris

(pentafluorophenyl)-4-(hydroxyphenyl) borate and an organometallic
compound, for example trimethylaluminum.
Thus according to another aspect of the present invention there is
provided a process for the polymerization of olefin monomers selected
from (a) ethylene, (b) propylene, (c) mixtures of ethylene and propylene,
and (d) mixtures of (a), (b), or (c) with one or more other alpha olefins, said
process performed in the presence of a supported transition metal catalyst
system as hereinbefore described.
The supported transition metal catalysts of the present invention
may be used for the polymerization of olefins in solution, slurry or the gas
phase.
A slurry process typically uses an inert hydrocarbon diluent and
temperatures from about 0°C up to a temperature just below the
temperature at which the resulting polymer becomes substantially soluble
in the inert polymerization medium. Suitable diluents include toluene or
alkanes such as hexane, propane or isobutane. Preferred temperatures
are from about 30°C up to about 200°C but preferably from about 60°C to
100°C. Loop reactors are widely used in slurry polymerization processes.
The preferred process for the present invention is the gas phase.
Suitable gas phase processes of the present invention include the
polymerization of alpha olefins, especially for the homopolymerization and
the copolymerization of ethylene with alpha olefins for example 1-butene,
1-hexene, 4-methyl-1-pentene are well known in the art. Particularly
preferred gas phase processes are those operating in a fluidized bed.
Examples of such processes are described in EP 89691 and EP
699213, the latter being a particularly preferred process for use with the
supported catalysts of the present invention.
Particularly preferred polymerization processes are those
comprising the polymerization of ethylene or the copolymerization of
ethylene and a-olefins having from 3 to 10 carbon atoms.
Thus, according to another aspect of the present invention there is
provided a process for the polymerization of ethylene or the

Catalyst B - Inventive
Grace-Davison Sylopol 2408 silica was dehydrated in a manner that
reduced the total residual volatiles in the silica to 0.9 % by weight. The
remaining surface hydroxyl groups in the silica were chemically passified
in the following manner.
130 g of the dehydrated Sylopol 2408 silica was slurried in 300 mL
of dry, degassed heptane under an inert atmosphere. 156 mL of a 25
weight percent solution of triethyl aluminum (TEAL) in toluene was then
added to the silica slurry. An additional 150 mL of heptane was then
added. The mixture was swirled by hand and then placed on a rotational
agitator, at slow speed, for 3 hours. The solids were then recovered by
filtration and washed three times with 200 mL of heptane. The washed
solids were then vacuum dried to a residual pressure of 300 millitorr.
118.5 g of the TEAL-passified silica was placed in a 1 L, pear-
shaped flask. In a separate 125 mL hypo-vial, 52.8 mL of a 9.7 weight
percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)}, known
as B-2, and 15.8 mL of 0.25 molar TEAL in toluene were mixed and
allowed to sit for 5 minutes. This solution was then added to the TEAL-
passified silica in the 1 L flask and mixed slowly on the rotational agitator
for 1 hour. 24.5 mL of a 10 weight percent solution of
(pentafluorophenylcyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium
dichloride in toluene was then added to the 1 L flask which was then mixed
on the rotational agitator for an additional 1 hour. This corresponds to a
boron:titanium mole ratio of about 1.05:1. 400 mL of heptane was added
to the flask, which was then further mixed on the rotational agitator for 1
hour. Solid catalyst was recovered by filtration and washed three times
with 250 mL of heptane. The washed catalyst was then dried under
vacuum to a residual pressure of 300 millitorr. Metal contents in the
supported catalyst were measured to be 0.148 weight percent titanium and
2.6 weight percent aluminum.

copolymerization of ethylene and a-olefins having from 3 to 10 carbon
atoms, said process performed under polymerization conditions in the
present of a supported transition metal catalyst system prepared as
hereinbefore described.
EXAMPLES
Part A - Catalyst Synthesis
Catalyst A - Comparative
A commercially available silica (Sylopol 2408, from W.R. Grace-
Davison) was dehydrated in a manner that reduced the total residual
volatiles in the silica to 0.6 % by weight. A supported catalyst, using this
dehydrated silica as the support, was prepared in the following manner.
29.00 kg of dehydrated Sylopol 2408 silica was slurried in a minimal
amount of toluene under inert atmospheric conditions. 33.67 kg of a 30
weight percent solution of a commercially available methylaluminoxane
(MAO purchased from Albemarle) in toluene was metered into the mixture.
Upon completion of the MAO addition, the slurry was stirred for an
additional 30 minutes. At this point, the slurry was sampled to determine
the Al content in the MAO-silica solids and the supernatant liquid. Al
content was determined to be 10.9 weight percent in the MAO-silica solid
and 539 ppm by weight in the supernatant liquid indicating essentially
complete supporting of MAO at this stage. 730.1 g of
(pentafluorophenylcyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium
dichloride was dissolved in a minimal amount of toluene and added to the
MAO-silica slurry. The mixture was then stirred for 1 hour. At this point
the slurry concentration was such that the concentration was 25 weight
percent solids based on theoretical calculation of the final mass of
supported catalyst expected. The slurry was decanted and washed a total
of three times with hexane to remove toluene prior to drying. Analysis of
the recovered catalyst indicated 11.1 weight percent aluminum, 0.175
weight percent titanium (AI:Ti = 112.6 mole:mole) and 1.3 weight percent
residual volatiles.

Catalyst C - Comparative
Grace-Davison Sylopol 2408 silica was dehydrated in a manner that
reduced the total residual volatiles in the silica to 0.9 % by weight. A
supported catalyst, using this dehydrated silica as the support, was
prepared in the following manner.
144.7 g of dehydrated Sylopol 2408 silica was slurried in a minimal
amount of toluene under inert atmospheric conditions. 185 mL of a 30
weight percent solution of Albemarle methylaluminoxane (MAO) in toluene
was added into the mixture. Upon completion of the MAO addition, the
slurry was stirred for an additional 30 minutes 4.22 g of (1-ethyl-2-
pentafluorophenyl-cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium
dichloride was dissolved in a minimal amount of toluene and added to the
MAO-silica slurry. The mixture was then stirred for 1 hour. The slurry was
decanted and washed a total of three times with hexane to remove toluene
prior to drying under vacuum to a residual pressure of 300 millitorr. The
finished catalyst contained 0.173 percent titanium by weight.
Catalyst D
Grace-Davison Sylopol 2408 silica was dehydrated in a manner that
reduced the total residual volatiles in the silica to 0.9 % by weight. The
remaining surface hydroxyl groups in the silica were chemically passified
in the following manner.
130 g of the dehydrated Sylopol 2408 silica was slurried in 300 mL
of dry, degassed heptane under an inert atmosphere. 156 mL of a 25
weight percent solution of triethyl aluminum (TEAL) in toluene was then
added to the silica slurry. An additional 150 mL of heptane was then
added. The mixture was swirled by hand and then placed on a rotational
agitator, at slow speed, for 3 hours. The solids were then recovered by
filtration and washed three times with 200 mL of heptane. The washed
solids were then vacuum dried to a residual pressure of 300 millitorr.
94.7 g of the TEAL-passified silica was placed in a 1 L, pear-
shaped flask. In a separate 125 mL hypo-vial, 42.3 mL of a 9.7 weight
percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)}, known

as B-2, and 12.6 mL of 0.25 molar TEAL in toluene were mixed and
allowed to sit for 5 minutes. This solution was then added to the TEAL-
passified silica in the 1 L flask and mixed slowly on the rotational agitator
for 1 hour. 20.6 mL of a 10 weight percent solution of (1-ethyl-2-
pentafluorophenyl-cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium
dichloride in toluene was then added to the 1 L flask which was then mixed
on the rotational agitator for an additional 1 hour. 400 mL of heptane was
added to the flask, which was then further mixed on the rotational agitator
for 1 hour. Solid catalyst was recovered by filtration and washed three
times with 250 mL of heptane. The washed catalyst was then dried under
vacuum to a residual pressure of 300 millitorr. The finished catalyst
contained 0.148 percent titanium by weight.
Catalyst E
Grace-Davison Sylopol 2408 silica was dehydrated in a manner that
reduced the total residual volatiles in the silica to 0.9 % by weight. The
remaining surface hydroxyl groups in the silica were chemically passified
in the following manner.
130 g of the dehydrated Sylopol 2408 silica was slurried in 300 mL
of dry, degassed heptane under an inert atmosphere. 156 mL of a 25
weight percent solution of triethyl aluminum (TEAL) in toluene was then
added to the silica slurry. An additional 150 mL of heptane was then
added. The mixture was swirled by hand and then placed on a rotational
agitator, at slow speed, for 3 hours. The solids were then recovered by
filtration and washed three times with 200 mL of heptane. The washed
solids were then vacuum dried to a residual pressure of 300 millitorr.
118.8 g of the TEAL-passified silica was placed in a 1 L, pear-
shaped flask. In a separate 125 mL hypo-vial, 52.8 mL of a 9.7 weight
percent toluene solution of [(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)}, known
as B-2, and 15.8 mL of 0.25 molar TEAL in toluene were mixed and
allowed to sit for 5 minutes. This solution was then added to the TEAL-
passified silica in the 1 L flask and mixed slowly on the rotational agitator
for 1 hour. 27.0 mL of a 10 weight percent solution of (1-n-butyl-2-

pentafluorophenyl-cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium
dichloride in toluene was then added to the 1 L flask which was then mixed
on the rotational agitator for an additional 1 hour. 400 mL of heptane was
added to the flask, which was then further mixed on the rotational agitator
for 1 hour. Solid catalyst was recovered by filtration and washed three
times with 250 mL of heptane. The washed catalyst was then dried under
vacuum to a residual pressure of 300 millitorr. The finished catalyst
contained 0.133 percent titanium and 2.5 percent aluminum by weight.
Catalysts F, G, and H
Grace-Davison Sylopol 948 silica was dehydrated at 250°C under a
nitrogen atmosphere for 5 hours, prior to use in the preparation of the
TEAL-passified silica described in the following section,
a) TEAL-passified Silica (SiO2/TEAL)
Add 650 mL of dry, degassed heptane to a 1 L, pear-shaped
flask, followed by 11.25 of a 0.29 wt % solution of Stadis® 425
(Octel Starrion L.L.C.) in heptane and 150 g of calcined Sylopol 948
silica. The flask was placed on the rotating arm of a rotary
evaporator and turned slowly for 15 minutes. 100 mL of a 25 wt %
TEAL in hexane solution was added to the flask and then swirled by
hand (Note: there is some heat evolution). 75 mL of 25 wt % TEAL
in hexane was then added. The flask was then placed on the
rotating arm of a rotary evaporator and turned slowly for 1 hour.
The slurry was filtered. The filter cake was transferred back to the
flask, reslurried in 350 mL of heptane and rotated for an additional
30 minutes. The slurry was filtered. The filter cake was transferred
back to the flask, reslurried in 350 mL of heptane and rotated for an
additional 30 minutes. The slurry was filtered a third time. The filter
cake was transferred back to the flask, reslurried in 350 mL of
heptane along with 11.25 mL of the 0.29 wt % solution of Stados®
425 in heptane. The flask was placed on the rotating arm of a
rotary evaporator and turned slowly for 15 minutes. The solvent

was then removed under vacuum while heating to 60°C to reach a
final vacuum of 300 millitorr.
b) Supported Catalyst Preparation
Supported catalysts F, G and H were prepared according the
following recipe and differ only in the choice and amount of catalyst
precursor molecule.
Working in a glovebox under inert atmospheric conditions,
1.43 mL of a 9.58 weight percent toluene solution of
[(C18H37)2CH3NH]}(C6F5)3B(C6H4OH)} and 0.42 mL of 0.25 molar
TEAL in toluene were mixed in a 100 mL round-bottomed flask and
allowed to sit for 5 minutes. 1.61 g of SiO2/TEAL was then added
and the mixture was shaken on a Lab-Line Mistral Multi-Mixer at
high speed for 1 hour. The appropriate amount of a solution of the
catalyst precursor molecule in heptane was premixed with 0.3 mL of
dry, degassed hexene in a hypo-vial and swirled on the Multi-Mixer
gently for 15 minutes. For Catalyst F, 0.85 mL of 10 wt %
(dimethyl)(1-n-butyl-2-pentafluorophenyl-cyclopentadienyl)(tri-
tertiarybutylphosphinimido)titanium in heptane was premixed with
the 0.3 mL of hexene. For Catalyst G, 1.05 mL of 8 wt %
(dimethyl)(2-pentafluorophenyl-indenyl)(tri-
tertiarybutylphosphinimido)titanium in heptane was premixed with
the 0.3 mL of heptane. For Catalyst H, 0.53 mL of 10 wt %
(dimethyl)(cyclopentadienyl)(tri-tertiarybutylphosphinimido)titanium
in heptane was premixed with the 0.3 mL of hexene. The molecule
plus hexene solution was then added to the flask containing the
support plus activator material. The flask was then shaken for 1
hour. 0.20 mL of a 2g/L solution of Stadis® 425 (available from
Octel Starrion L.L.C.) in heptane was then added to the mixture
followed by an additional 15 minutes of mixing. The flask was then
placed under vacuum and dried to a residual pressure of 300
millitorr. Finished catalyst F contained 0.202 percent titanium by
weight. Finished catalyst G contained 0.212 percent titanium by

weight. Finished catalyst H contained 0.320 percent titanium by
weight.
Part B - Ethylene Homopolvmerization
Ethylene homopolymerization experiments were conducted on a
2 L, stirred, autoclave reactor in gas phase operation. The
polymerizations were run at 85°C for 60 minutes under an ethylene
pressure of 200 psig. During reactor conditioning and setup, 0.4 mL of a
25 weight percent solution of tri-isobutylaluminum (TiBAL) was used as an
impurity scavenger to assist with purification of reactor internals and the
seedbed (which was 130 grams of granular high density polyethylene
"HDPE"). Prior to initiation of polymerization, 25 - 30 mg of catalyst was
loaded into an injection tube under anaerobic conditions in a glovebox and
was then connected to the reactor. A portion of the ethylene gas used to
create the 200 psig pressure was used to push the catalyst into the reactor
to initiate polymerization. Throughout the polymerization, ethylene was
allowed to flow to the reactor through a mass flow meter to maintain a
constant pressure of 200 psig. Measurement of this ethylene flow rate
over time provided a measure of polymerization rate as a function of time.
Ethylene homopolymerization details are provided in Table 1.

Part C - Copolvmerization
Ethylene-hexene copolymerization experiments were conducted on
a 2 L, stirred, autoclave reactor in gas phase operation.
Copolymerizations were run at 85°C for 60 minutes with a total operating
pressure of 200 psig. Gas phase compositions for ethylene and hexene
were controlled via closed-loop process control to values of 40.0 and 0.20
mole percent, respectively. Hydrogen was metered into the reactor in a
molar feed ratio of 0.0014 relative to ethylene feed during polymerization.
Nitrogen constituted the remainder of the gas phase mixture
(approximately 59.2 mole %). During reactor conditioning and setup, 0.4
mL of a 25 weight percent solution of tri-isobutylaluminum (TiBAL) was
used as an impurity scavenger to assist with purification of reactor
internals and the 130 g HDPE seedbed. Catalysts (see Table 2) were
loaded into an injection tube under anaerobic conditions in a glovebox and
was then connected to the reactor. A portion of the nitrogen used to make
up the reactor gas composition was used to push the catalyst into the
reactor at the start of polymerization. The reactor was vented at a
controlled rate throughout the polymerization, which in combination with
gas consumption due to polymerization allowed for maintenance of
controlled gas phase composition through the copolymerization reaction.
The details of the ethylene-hexene copolymerizations performed in
the presence of added hydrogen are given in Table 2.

Physical characterization data for the polymers produced in
Examples 6 to 10 are also presented in Table 2. The data in Table 2
indicate that the inventive catalysts provide good comonomer
incorporation in ethylene-hexene copolymerizations.
A second set of ethylene-hexene copolymerization experiments
were run under the following conditions.
Copolymerizations were run at 70°C for 60 minutes with a total
operating pressure of 300 psig. Gas phase compositions for ethylene and
hexene were controlled via closed-loop process control to values of 50.0
and 0.14 mole percent, respectively. Hydrogen was metered into the
reactor in a molar feed ratio of 0.00168 relative to ethylene feed during
polymerization. Nitrogen constituted the remainder of the gas phase
mixture (approximately 49.2 mole %). During reactor conditioning and
setup, 0.4 mL of a 25 weight percent solution of tri-isobutylaluminum
(TiBAL) was used as an impurity scavenger to assist with purification of
reactor internals and the 100 g HDPE seedbed. Catalysts (see Table 3)
were loaded into an injection tube under anaerobic conditions in a
glovebox and was then connected to the reactor. A portion of the nitrogen
used to make up the reactor gas composition was used to push the
catalyst into the reactor at the start of polymerization. The reactor was
vented at a controlled rate throughout the polymerization, which in
combination with gas consumption due to polymerization allowed for
maintenance of controlled gas phase composition through the
copolymerization reaction.
The details of the ethylene-hexene copolymerizations performed in
the presence of added hydrogen are given in Table 3.

Use of the statistical t-test comparing the productivity of Catalyst H
to either Catalyst F or Catalyst G indicates that Catalyst F and Catalyst G
give productivities approximately double that seen for Catalyst H with a
greater than 99 percent confidence level.
INDUSTRIAL APPLICABILITY
A supported catalyst for olefin polymerization comprising a specific
type of activator, a specific organometallic catalyst species and a support
which is preferably a metal oxide. The supported catalyst is especially
suitable for slurry or gas phase polymerizations and exhibits very high
activity in gas phase polymerizations. The polyethylene produced with this
catalyst is suitable for the production of a wide variety of goods, ranging
from flexible plastic films to rigid plastic containers.

WE CLAIM:

1. A supported catalyst comprising:
(a) (1) a support material;
(a) (2) an organometal or metalloid compound wherein the metal or metalloid is selected from
the group consisting of magnesium, zinc, boron, aluminium, germanium, tin, lead, and
mixtures thereof; and
(b) an activator compound comprising:
(b)(1) a cation which is capable of reacting with a transition metal metallocene compound to
form a transition metal complex which is catalytically active for the polymerization of
alpha-olefins;
(b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one
substituent comprising a moiety having an active hydrogen; and
(c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the
formula:

wherein M is a group 4 metal; * Cp is a substituted eta-5 bonded cyclopentadienyl ligand which
contains from 7 to 30 carbon atoms; PI is a phosphinimine ligand; L is a leaving group ligand;
and n is 1 or 2, depending upon the valence of m, with the further provisos that:

a) said catalyst contains from 1 to 2,000 mu.mol of activator compound per gram of support
material; and
b) *Cp is selected from the group consisting of 2-pen-tafluorophenyl cyclopentadienyl, tri-
butyl-2- pentafluorophenyl cyclopentadienyl and 2-pentafluorophenyl indenyl.
2. The supported catalyst of claim 1 wherein M is Ti.

ABSTRACT

Title: SUPPORTED POLYMERIZATION CATALYSTS
A supported catalyst comprising:
(a) (1) a support material;
(a) (2) an organometal or metalloid compound wherein the metal or metalloid is selected from
the group consisting of magnesium, zinc, boron, aluminum, germanium, tin, lead, and
mixtures thereof; and
(b) an activator compound comprising:
(b)(1) a cation which is capable of reacting with a transitin metal metallocene compound to
form a transition metal complex which is catalytically active for the polymerization of
alpha-olefins;
(b)(2) a compatible anion having up to 100 nonhydrogen atoms and containing at least one
substituent comprising a moiety having an active hydrogen; and
(c) phosphinimine/substituted cyclopentadienyl organometallic complex according to the
formula:

wherein M is a group 4 metal; * Cp is a substituted eta-5 bonded cyclopentadienyl ligand which
contains from 7 to 30 carbon atoms; PI is a phosphinimine ligand; L is a leaving group ligand;
and n is 1 or 2, depending upon the valence of m, with the further provisos that:
c) said catalyst contains from 1 to 2,000 mu.mol of activator compound per gram of support
material; and
d) *Cp is selected from the group consisting of 2-pen-tafluorophenyl cyclopentadienyl, tri-
butyl-2- pentafluorophenyl cyclopentadienyl and 2-pentafluorophenyl indenyl.

Documents:

4612-KOLNP-2008-(02-08-2012)-CORRESPONDENCE.pdf

4697-KOLNP-2008-(10-01-2012)-ABSTRACT.pdf

4697-KOLNP-2008-(10-01-2012)-CLAIMS.pdf

4697-KOLNP-2008-(10-01-2012)-CORRESPONDENCE.pdf

4697-KOLNP-2008-(10-01-2012)-DESCRIPTION (COMPLETE).pdf

4697-KOLNP-2008-(10-01-2012)-FORM-1.pdf

4697-KOLNP-2008-(10-01-2012)-FORM-2.pdf

4697-KOLNP-2008-(10-01-2012)-FORM-3.pdf

4697-KOLNP-2008-(10-01-2012)-OTHERS PCT FORM.pdf

4697-KOLNP-2008-(10-01-2012)-OTHERS.pdf

4697-kolnp-2008-abstract.pdf

4697-kolnp-2008-claims.pdf

4697-KOLNP-2008-CORRESPONDENCE 1.1.pdf

4697-kolnp-2008-correspondence.pdf

4697-kolnp-2008-description (complete).pdf

4697-KOLNP-2008-EXAMINATION REPORT.pdf

4697-kolnp-2008-form 1.pdf

4697-KOLNP-2008-FORM 18 1.1.pdf

4697-kolnp-2008-form 18.pdf

4697-kolnp-2008-form 2.pdf

4697-KOLNP-2008-FORM 26.pdf

4697-kolnp-2008-form 3.pdf

4697-kolnp-2008-form 5.pdf

4697-KOLNP-2008-GRANTED-ABSTRACT.pdf

4697-KOLNP-2008-GRANTED-CLAIMS.pdf

4697-KOLNP-2008-GRANTED-DESCRIPTION (COMPLETE).pdf

4697-KOLNP-2008-GRANTED-FORM 1.pdf

4697-KOLNP-2008-GRANTED-FORM 2.pdf

4697-KOLNP-2008-GRANTED-FORM 3.pdf

4697-KOLNP-2008-GRANTED-FORM 5.pdf

4697-KOLNP-2008-GRANTED-SPECIFICATION.pdf

4697-KOLNP-2008-INTERNATIONAL PRELIMINARY EXAMINATION REPORT 1.1.pdf

4697-kolnp-2008-international preliminary examination report.pdf

4697-kolnp-2008-international publication.pdf

4697-kolnp-2008-international search report.pdf

4697-KOLNP-2008-OTHERS.pdf

4697-kolnp-2008-pct priority document notification.pdf

4697-kolnp-2008-pct request form.pdf

4697-KOLNP-2008-REPLY TO EXAMINATION REPORT.pdf

4697-kolnp-2008-specification.pdf

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Patent Number

256781

Indian Patent Application Number

4697/KOLNP/2008

PG Journal Number

31/2013

Publication Date

02-Aug-2013

Grant Date

29-Jul-2013

Date of Filing

19-Nov-2008

Name of Patentee

INEOS EUROPE LIMITED

Applicant Address

COMPASS POINT, 79-87 KINGSTON ROAD, STAINES MIDDLESEX TW18 1DT

Inventors:

#	Inventor's Name	Inventor's Address
1	JEREMIC, DUSAN	240 SANDSTONE DRIVE NW, CALGARY ALBERTA T3K 3S6
2	MCKAY, IAN	96 CASTLEGLEN ROAD NE, CALGARY, ALBERTA T3J 1T1
3	JACOBSEN, GRANT, BERENT	RINGLAAN 59, B-3080 TERVUREN
4	MASTROIANNI, SERGIO	COURS SAINT MICHEL N92 ETTERBEEK, B-1040 BRUXELLES

PCT International Classification Number

C08F 10/00,C08F 4/02

PCT International Application Number

PCT/CA2007/000736

PCT International Filing date

2007-05-02

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	0610667.8	2006-05-30	U.K.