Molybdenum and tungsten compounds that are useful as catalyst precursors in the metathesis of olefins have the general formula:
M(Y)(OR2)x (R3)y (X)z Ls
wherein M is tungsten or molybdenum; Y is oxygen or NR1 ; R1, R2, and R3 are the same or different and are selected from alkyl, cycloalkyl, cycloalkenyl, polycycloalkyl, polycycloalkenyl, haloalkyl, haloaralkyl, substituted or unsubstituted aralkyl and aryl groups, and silicon-containing analogs thereof; L is a lewis base; X is halogen; s is 0 or 1; x+y+z=4, and y≧1, provided that when x is 2 or more, two OR2 groups can be replaced by a chelating ligand (OR2)2.
These compounds can be used for the metathesis of olefins in neat metathesizable olefin, as well as in solution, and require only the input of energy to be converted to active catalysts.
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8. An olefin metathesis catalyst precursor having the formula:
M(Y)(OR2)x (R3)y (X)z Ls wherein M is molybdenum or tungsten; Y is oxygen; X is halogen; L is a lewis base; s is 0 or 1; x+y+z=4, and y >1, provided that when x is 2 or more, two OR2 groups can be replaced by a chelating ligand (OR2)2, wherein OR2 =OCH2 CMe3, R3 =CH2 CMe2 Ph, x=2, and y=2. 7. An olefin metathesis catalyst precursor having the formula:
M(Y)(OR2)x (R3)y (X)z Ls wherein M is molybdenum or tungsten; Y is NC6 H3 -2,6-i-Pr2 ; X is halogen; L is a lewis base; s is 0 or 1; x+y+z=4, and y>1, provided that when x is 2 or more, two OR2 groups can be replaced by a chelating ligand (OR2)2, wherein OR2 =OCMe(CF3)2, R3 =CH2 CMe2 Ph, x=2, and y=2, wherein Me is a methyl group. 5. An olefin metathesis catalyst precursor having the formula:
M(Y)(OR2)x (R3)y (X)z Ls wherein M is molybdenum or tungsten; Y is NC6 H3 -2,6-i-Pr2 ; X is halogen; L is a lewis base; s is 0 or 1; x+y+z=4, and y>1, provided that when x is 2 or more, two OR2 groups can be replaced by a chelating ligand (OR2)2, wherein OR2 =OCMe3, R3 =CH2 CMe2 Ph, x=2, and y=2, wherein i-Pr is an isopropyl group, Me is a methyl group, and Ph is a phenyl group. 1. An olefin metathesis catalyst precursor having the formula:
M(Y)(OR2)x (R3)y Ls wherein M is molybdenum or tungsten; Y is oxygen or NR1 ; R1 and R2 are the same or different and are selected from the group consisting of C6 H3 -2,6-i-Pr2, CMe3, C(CF3)3, CMe(CF3)2, and CH2 CMe3 ; R3 is selected from the group consisting of CH2 CMe2 Ph and CH2 CMe3, where Me is a methyl group, Ph is a phenyl group, and i-Pr is an isopropyl group; except when R2 is CMe3, then R3 cannot simultaneously be CH2 CMe3 ; L is a lewis base; s is 0 or 1; and x+y=4. 3. An olefin metathesis catalyst precursor selected from the group consisting of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OCH2 CMe3)2 (CH2 CMe3)2, W(NC6 H3 -2,6-i-Pr2) (OC(CF3)3)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2 (CH2 CMe2 Ph)2, WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2, Mo(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2, Mo(NC6 H3 -2,6-i-Pr2) (OCH2 CMe3)2 (CH2 CMe3)2, Mo(NC6 H3 -2,6-i-Pr2) (OC(CF3)3)2 (CH2 CMe2 Ph)2, Mo(NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2 (CH2 CMe2 Ph)2, and MoO(OCH2 CMe3)2 (CH2 CMe2 Ph)2, where Me is a methyl group, Ph is a phenyl group, and i-Pr is an isopropyl group.
4. An olefin metathesis catalyst precursor having the formula:
M(Y)(OR2)x (R3)y (X)z Ls wherein M is molybdenum or tungsten; Y is oxygen or NR1 ; R1, R2, and R3 are the same or different and are selected from the group consisting of alkyl, cycloalkyl, cycloalkenyl, polycycloalkyl, polycycloalkenyl, haloalkyl, haloaralkyl, substituted or unsubstituted aralkyl and aryl groups, and silicon-containing analogs thereof; X is halogen; L is a lewis base; s is 0 or 1; x+y+z=4; y>1; x is 2 or more; and two OR2 groups are replaced by a chelating ligand (OR2)2, wherein the chelating ligands are selected from the group consisting of 3,5-di-tert-butylcatechol; 2,2'-methylenebis(4-chlorophenol); catechol; binaphtholate; pinacol; perfluoropinacol; benzopinacol; 2,2'-methylenebis(4-methyl-6-butylphenol); 2,2'-methylenebis(4-ethyl-6-butylphenol); 4,4'-methylenebis(2,6-tert-butylphenol); 2,2'-ethylenebis(4,6-di-tert-butylphenol); 2,2'-methylenebis(4-ethyl-6-(1-methylcyclohexyl)phenol; 4,4'-butylidenebis(6-tert-butyl-2-methylphenol); 4,4'-thiobis (6-tert-butyl-3-methylphenol; 4,4'-methylenebis (2,6-dimethylphenol); 1,1'-thiobis(2-naphthol); 2,2'-isobutylindenebis (4,6-tert-butylphenol); 2,2'-isobutylindenebis(4,6-dimethylphenol), and 2,2'-methylenebis(4-methyl-6-cyclohexyl)phenol. 2. The catalyst precursor of
6. The catalyst precursor of
9. The catalyst precursor of
10. The catalyst precursor of
wherein the chelating ligands are selected from the group consisting of 3,5-di-tert-butylcatechol; 2,2'-methylenebis (4-chlorophenol); catechol; binaphtholate; pinacol; perfluoropinacol; benzopinacol; 2,2'-methylenebis (4-methyl-6-butylphenol); 2,2'-methylenebis(4-ethyl-6-butylphenol); 4,4'-methylenebis(2,6-tert-butylphenol); 2,2'-ethylenebis(4,6-di-tert-butylphenol); 2,2'-methylenebis(4-ethyl-6-(1-methylcyclohexyl)phenol; 4,4'-butylidenebis (6-tert-butyl-2-methylphenol); 4,4'-thiobis(6-tert-butyl-3-methylphenol; 4,4'-methylenebis(2,6-dimethylphenol); 1,1'-thiobis(2-naphthol); 2,2'-isobutylindenebis(4,6-tert-butylphenol); 2,2'-isobutylindenebis(4,6-dimethylphenol), and 2,2'-methylenebis(4-methyl-6-cyclohexyl)phenol.
11. The catalyst precursor of
12. The catalyst precursor of
13. The catalyst precursor of
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This invention relates to tungsten and molybdenum compounds that are useful as catalyst precursors for olefin metathesis reactions, and to novel methods for synthesizing these compounds. This invention also relates to new molding techniques using olefin metathesis catalyst precursors.
The olefin metathesis process can be defined as the redistribution of alkylidene moieties to give a mixture of olefins, e.g., propylene is converted to ethylene and butylene. The simplest example is:
2 R'CH═CHR⇄RCH═CHR+R'CH═CHR'
The reaction proceeds by addition of an olefin to a catalyst having a metal-carbon double bond ( M!═CHR; metal alkylidene complex) to give a metallacyclobutane ring, which then releases an olefin to reform a metal-alkylidene complex. A typical olefin of interest that will undergo metathesis in the presence of an appropriate catalyst is an ester of oleic acid, cis-CH3 (CH2)7 CH═CH(CH2)7 CO2 H.
Ring-opening metathesis polymerization (ROMP) of cycloolefins by olefin metathesis catalysts is an extremely important facet of the olefin metathesis reaction that results in the preparation of thermoset and thermoplastic polymers. Monocyclic olefins, substituted monocyclics, polycyclic and substituted polycyclic olefins have all been employed in the preparation of unsaturated polymers. In many cases, cycloolefins can be polymerized even when they contain polar or reactive functional groups. Norbornene is a typical olefin that will undergo ROMP in the presence of an olefin metathesis catalyst having a metal-carbon double bond.
A third type of olefin metathesis reaction is acyclic diene metathesis (ADMET). ADMET chemistry can be used to form dimers, oligomers, or polymers. ADMET polymerization is a viable synthetic route to high molecular weight polymers and copolymers, but it is an inherently more complicated process than ring-opening metathesis polymerization (ROMP). ROMP is a chain growth, addition-type polymerization driven by the alleviation of ring strain. The ADMET reaction is a step propagation condensation reaction. The ADMET reaction is an equilibrium process wherein the product is generated by the removal of an olefin, typically ethylene, from the reaction. Thus, in the ADMET (or simple olefin metathesis) reaction of styrene (a monoolefin), quantitative metathesis chemistry occurs yielding the expected dimer of trans-stilbene. At high conversion, ADMET polymerization of 1,9-decadiene (an α,ω-diolefin) yields poly(octylene). When ADMET polymerization reactions are terminated before reaching ≈99% conversion, the α,ω-diolefins employed generate oligomers, since step growth polymerization only produces high molecular weight polymer at very high conversions. An important aspect of ADMET polymerization is that ester and ether functionalities are often tolerated on the time scale of the polymerization reaction, and polymers can be prepared that are not directly available in a ROMP reaction.
Because the ADMET reaction is a step growth equilibrium condensation reaction, it provides the opportunity to shift the equilibrium between monomer and polymer. It has been found that unsaturated polymers, such as polynorbornene and polybutadiene, can be depolymerized in combination with ethylene to yield low molecular weight oligomers and α,ω-alkadienes.
The olefin metathesis reaction has also been employed in ring-closing metathesis of acyclic diene ethers to form cyclic and acyclic olefins (Fu and Grubbs, J. Am. Chem. Soc. 1992, Vol. 114, p. 5426-27). For example, various diallyl ethers when treated with a well-defined alkylidene complex, Mo(CHCMe2 Ph)(NC6 H3 -2,6-i-Pr2)(OCMe(CF3)2)2, lead to a number of ring-closed derivatives, i.e., cyclic ethers, amines and amides.
To reap the benefits of functionalized olefin metathesis, ring-opening metathesis, ring-closure chemistry, and the ADMET chemistry described above, the trend has been towards the formation of less Lewis acidic, well-characterized catalyst species based on a variety of transition metals including tungsten and molybdenum. These catalysts should be simple to prepare, of known structure, and with a reactivity that can be controlled. Several of these types of compounds have been shown to metathesize olefins with an activity that can be regulated through the choice of aryloxide or alkoxide ligands. For examples, see J. M. Basset et al., Angew. Chem., 1992, Vol. 104, p. 622-664; J. A. Osborn et al., J. Chem. Soc., Chem. Commun., 1989, p. 1062-1063; R. R. Schrock, U.S. Pat. Nos. 4,681,956 and 4,727,215, and R. R. Schrock et al., U.S. Pat. No. 5,142,073.
Tungsten and molybdenum catalysts, M(═CHR3) (NR1) (OR2)2, reported by R. R. Schrock have been employed in all of the areas of olefin metathesis described above. These well-defined transition metal alkylidene complexes have a high tolerance for functionalized groups as well as temperature. Molybdenum and tungsten alkylidene complexes of the following compositions are particularly useful: Mo(CHCMe2 Ph) (NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2, Mo(CHCMe3) (NC6 H3 -2,6-i-Pr2) (OCMe3)2, Mo(CHCMe3) (NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2, W(NC6 H3 -2,6-i-Pr2) (CHCMe2 Ph) (OCMe3)2, W(NC6 H3 -2,6-i-Pr2) (CHCMe3) (OCMe3)2, W(NC6 H3 -2,6-i-Pr2) (CHCMe2 Ph) (OCMe(CF3)2)2, W(NC6 H3 -2,6-i-Pr2) (CHCMe3) (OCMe(CF3)2)2, W(NC6 H3 -2,6-i-Pr2) (CHCMe2 Ph)2 (OCMe(CF3))2, and W(NC6 H3 -2,6-i-Pr2) (CHCMe2 Ph)2 (OC(CF3) (CF2 CF3)2. These catalysts, however, are typically prepared using multistep synthetic routes that are quite labor intensive and often use expensive reagents.
The simple olefin metathesis reaction and ring-opening metathesis polymerization synthesis of specialty polymers using these catalysts are performed in homogeneous phase by reacting the olefin with the alkylidene species in a solvent. The ADMET reaction employing these catalysts can be performed both in solution and in bulk monomer.
In the manufacture of thermoset polymers, it is desirable to have a solventless system so that solvent is not trapped within the polymer matrix. One disadvantage to the use of well-defined alkylidene catalysts is that they initiate polymerization (or olefin metathesis) immediately upon contact with a metathesizable monomer.
Reaction injection molding (RIM) of polyolefins by ring-opening of polyolefin metathesis polymerizable monomers in the presence of alkylidene complexes is a particularly important aspect of olefin metathesis. For example, Klosiewicz (U.S. Pat. Nos. 4,400,340 and 4,520,181) discusses a method whereby polydicyclopentadiene can be prepared by combining a plurality of reactant streams. One stream contains a metathesis catalyst and the second stream the activator for the metathesis system, and at least one contains dicyclopentadiene. After mixing the streams and generating a metathesis catalyst, the mixture is immediately injected into a mold where polymerization takes place. Although such catalysts are very effective species for polymerization, residual amounts of chlorine or solvent for the dissolution of the catalyst precursor or activator are retained in the thermoset product.
A family of olefin metathesis catalyst precursors has been discovered whose members are regarded as unicomponent catalyst precursors, since they require no chemical activator. The use of Lewis base rate moderators in this system is optional.
Specifically, this invention relates to the generation of olefin metathesis catalysts by thermal activation or activation by some other energy input of single compounds (olefin metathesis catalyst precursors) or mixtures of catalyst precursors. This activation can occur in a solvent or in an olefin metathesizable monomer. The catalyst precursors of this invention comprise transition metal-based compounds that provide facile conversion to the corresponding olefin metathesis catalysts.
Such catalyst precursors can be represented by the following structural formula:
M(Y) (OR2)x (R3)y (X)z Ls (I)
wherein M is molybdenum or tungsten; Y is oxygen or NR1 ; R1, R2, and R3 are selected from alkyl, cycloalkyl, cycloalkenyl, polycycloalkyl, polycycloalkenyl, haloalkyl, haloaralkyl, substituted or unsubstituted aralkyl and aryl groups, and silicon-containing analogs thereof; X is halogen; L is a Lewis base; s=0 or 1; x+y+z=4, and y≧1, provided that when x is 2 or more, two OR2 groups can be replaced by a chelating phenolate, catecholate, binaphtholate or chelating alcoholate ligand (OR2)2, e.g , pinacolato, benzopinacolato, and glycolate ligands.
These olefin metathesis catalyst precursors have proven useful in homogeneous, solventless olefin metathesis polymerization reactions. They are especially useful in the bulk ring-opening metathesis polymerization of mono- and polycyclic olefins (ROMP), especially norbornene, substituted norbornenes, dicyclopentadiene and higher polycyclic olefins. Both thermoset and thermoplastic polymers can be prepared. The olefin metathesis catalyst precursors are also useful in the depolymerization of unsaturated polymers, especially thermoset resins. The catalyst precursors can also be used for simple metathesis of olefins, acyclic diene metathesis (ADMET), and ring closure reactions.
In addition, the present invention also encompasses within its scope novel methods for the preparation of one particular class of metathesis catalysts having the following formula (II): M(═CHR4)(NR1)(OR2)2, wherein M is molybdenum or tungsten; R1 and R2 are the same or different and are selected from alkyl, cycloalkyl, cycloalkenyl, polycycloalkyl, polycycloalkenyl, haloalkyl, haloaralkyl, substituted or unsubstituted aryl and aralkyl groups, and silicon-containing analogs thereof; R4 is an alkyl, aryl, or aralkyl group or any substituent that results from the initial reaction between the M═CHR4 complex and the olefin that is to be metathesized. When R3 is a cycloalkyl, polycycloalkyl, cycloalkenyl, or polycycloalkenyl group, then (═CHR4) can be replaced by (═CRR'), where R and R' are hydrocarbon groups and together can form a cyclic structure. For example, a bis(cyclopentyl) complex generates a cyclopentylidene moiety. These compounds are catalysts for the metathesis of ordinary olefins (hydrocarbons), especially functionalized olefins, in the homogeneous phase. This method is more advantageous than prior methods because it requires a limited number of reaction steps, shorter reaction times, and lower cost starting materials. Moreover, this reaction provides for the easy synthesis of metathesis catalysts in the presence of an olefin metathesizable compound.
A principal object of the present invention is to provide olefin metathesis catalyst precursors that require only the input of energy and no chemical activator. Other advantages associated with these catalyst precursors are (i) the catalyst can be generated in situ either in neat monomer or, if desired, in a solvent, (ii) the catalyst can be synthesized very easily using low cost materials in a limited number of steps, (iii) the catalysts provide a simple, inexpensive, convenient preparative route to metathesis catalysts, and (iv) olefin metathesis thermoset polymers containing low levels of halogen can be produced.
The olefin metathesis catalyst precursors of this invention have the following structural formula:
M(Y) (OR2)x (R3)y (X)z Ls (I)
wherein M is molybdenum or tungsten; Y is oxygen or NR1 ; R1, R2, and R3 are the same or different and are selected from alkyl, cycloalkyl, cycloalkenyl, polycycloalkyl, polycycloalkenyl, haloalkyl, haloaralkyl, substituted or unsubstituted aralkyl and aryl groups, and silicon-containing analogs thereof; X is halogen, preferably chlorine or bromine, L is a Lewis base; s=0 or 1; x+y+z=4, and y≧1. In the case where x=2 or more, two OR2 groups can be replaced by a chelating phenolate, catecholate, binaphtholate or chelating alcoholate ligand (OR2)2, e.g., pinacolato, benzopinacolato, and glycolate ligands.
The term "polycycloalkyl" refers to groups containing two or more rings that share two or more carbon atoms, e.g., norbornane and adamantane. The term "cycloalkenyl" refers to cyclic groups containing unsaturation, i.e., cyclopentenyl. The term "polycycloalkenyl" refers to compounds containing two or more rings that share two or more atoms and also contain unsaturation, i.e., dicyclopentenyl. Silicon analogs of the carbon-containing groups listed for R1, R2, and R3 contain silicon atoms in place of one or more carbon atoms. For example, the silicon analog of the neopentyl moiety (Me3 CCH2 --) is the trimethylsilyl group (Me3 SiCH2 --).
The term aryl is employed here to denote a radical derived from a hydrocarbon, having solely aromatic unsaturation in six-membered carbocyclic rings, by removal of a hydrogen atom from a carbon atom of an aromatic ring. Examples of aryl groups are phenyl, naphthyl, 2,6-diisopropylphenyl, and 2,4,6-trimethylphenyl groups. Examples of araalkyl groups are benzyl and triphenylmethyl groups.
The following is a list of substituents that can be attached to the phenyl ring of the substituted aryl or aralkyl groups: Br, Cl, F, I, CH3, OCH3, SCH3, OC2 H5, cyclo-C3 H5, CF3, OCF3, NMe2, SO2 Me, C6 H5, CH2 C6 H5, OC6 H5, and 1-20 carbon alkyl groups, where Me is a methyl group.
The preferred substituents are selected from methyl, ethyl, propyl, isopropyl, butyl, tert-butyl, sec-butyl, hexyl, cyclohexyl, heptyl, octyl, nonyl, decyl, dodecyl, isopropenyl, phenyl, bromo, chloro, fluoro, ethoxy, methoxy, butoxy, octyloxy, hexadecyloxy, tetradecyloxy, octadecyloxy, pentoxy, phenoxy, cyclopropyl, trifluoromethyl (CF3), trifluoromethyloxy (OCF3), 1,1,2,2-tetrafluoroethoxy (OCF2 CF2 H), haloalkyl, dimethylamino (NMe2), methyl sulfonyl (SO2 Me), trifluoromethyl sulfonyl (SO2 CF3), aryl sulfonyl (SO2 Ar), and benzyl (CH2 C6 H5).
Preferred substituted phenyl groups are 2,6-dimethylphenyl, 2,6-dichlorophenyl, 2,6-diisopropylphenyl, 2,6-dibromophenyl, 2,6-difluorophenyl, 2,6-bis(trifluoromethyl)phenyl, 2,6-bis(trifluoromethoxy)phenyl, 3,5-bis(trifluoromethoxy)phenyl, 2,6-dimethoxyphenyl, 2-tert-butylphenyl, 2,5-di-tert-butylphenyl, 2,3,4,5,6-pentabromophenyl, 2-bromo-4,6-dimethylphenyl, 4-methylphenyl, 4-methoxy-2-methylphenyl, 2-tert-butyl-6-methylphenyl, 2-chloro-6-methylphenyl, and 2-methoxy-5-chlorophenyl.
Referring to (I), R1 is preferably selected from ethyl, tert-butyl, tert-octyl, perfluoro-tert-butyl ((CF3)3 C), perfluoro-2-methyl-2-pentyl, phenyl, 4-tert-octylphenyl, 2,6-dimethylphenyl, 2,4,6-trimethylphenyl, pentafluorophenyl, tri-tert-butylsilyl, triphenylmethyl, triphenylsilyl, 2,6-diisopropylphenyl, 2,6-dichlorophenyl, 2,6-dibromophenyl, 1-adamantyl, and 2-tert-butylphenyl.
R2 is preferably selected from tert-butyl, trifluoro-tert-butyl ((CF3) (CH3)2 C), hexafluoro-tert-butyl ((CF3)2 (CH3)C) , perfluoro-tert-butyl ((CF3)3 C), neopentyl (CH2 CMe3), neophyl (CH2 CMe2 Ph), where Ph=phenyl, perfluoro-2-methyl-2-pentyl, 2,6-dimethylphenyl, 2,6-diphenylphenyl, 2,4,6-trimethylphenyl, pentabromophenyl, pentafluorophenyl, trimethylsilyl, tri-tert-butylsilyl, triphenylsilyl, 2,6-diisopropylphenyl, 2,6-dibromophenyl, 2,6-dichlorophenyl, 2,4-dichloro-6-methylphenyl, 2,6-dibromo-4-chlorophenyl, 3,5-bis(trifluoromethyl)phenyl, 2,6-bis(trifluoromethoxy)phenyl, 2,6-bis(trifluoromethyl)phenyl, 2,6-dibromo-4-chlorophenyl, 2,6-dibromo-4-methylphenyl, 2,6-dibromo-4-tert-butylphenyl, 2,6-dibromo-4-tert-octylphenyl, 2,6-dibromophenyl, 2,6-dichloro-4-methylphenyl, 2,6-dichloro-4-methylsulfonylphenyl, 2,6-dichloro-4-tert-butylphenyl, or 2,6-dichloro-4-tert-octylphenyl.
R3 is preferably selected from neopentyl (CH2 CMe3), neophyl (CH2 CMe2 Ph), trimethylsilylmethyl (CH2 SiMe3), norbornyl, methyl, benzyl, and dicyclopentenyl. X is preferably chlorine or bromine, and L is preferably diethyl ether; acetonitrile; 4,4'-dimethyl-2,2'-bipyridine; 2,2'-bipyridine; 1,10-phenanthroline; dimethoxyethane; diethylene glycol dimethyl ether (diglyme); phosphorus compounds having the formula PR3 and R2 PCH2 CH2 PR2, in which R is an alkyl or aryl group; 1,4-diaza-1,3-butadienes having the formula RN═CH--CH═N--R, where R is an alkyl, substituted or unsubstituted aryl or aralkyl group; tetrahydrofuran; quinuclidine; pyridine; 4-phenylpyridine; tert-butylamine; 1-adamantylamine; aniline; 2,6-diisopropylaniline; 2,6-dimethylaniline, and 2-tert-butylaniline.
A Lewis base is a compound that is capable of donating a pair of electrons. Suitable Lewis bases, include, for example, diethyl ether; acetonitrile; tetrahydrofuran; 2,2'-bipyridine; 4,4'-dimethyl-2,2'-bipyridine; 1,10-phenanthroline; pyridine; dimethoxyethane; diethylene glycol dimethyl ether (diglyme); quinuclidine; 2-tert-butylaniline; 4-phenylpyridine; tert-butylamine; 1-adamantylamine; aniline; 2,6-diisopropylaniline; 2,6-dimethylaniline; phosphorus compounds having the formula PR3 and R2 PCH2 CH2 PR2, in which R is an alkyl or aryl group, and 1,4-diaza-1,3-butadienes having the formula RN═CH--CH═NR, where R is an alkyl, substituted or unsubstituted aryl or aralkyl group.
Bidentate ligands, i.e., (OR2)2 in formula (I), include, for example, chelating phenolate, catecholate, binaphtholate, or chelating alcoholate ligands, and are selected from the group consisting of 3,5-di-tert-butylcatechol; catechol; binaphtholate; pinacol (HOC(CH3)2 C(CH3)2 OH); perfluoropinacol (HOC(CF3)2 C(CF3)2 OH); benzopinacol (HOCPh2 CPh2 OH); 2,2'-methylenebis(4-methyl-6-butylphenol); 2,2'-methylenebis(4-chlorophenol); 2,2'-methylenebis(4-ethyl-6-butylphenol); 4,4'-methylenebis (2,6-di-tert-butylphenol); 2,2'-ethylenebis(4,6-di-tert-butylphenol); methylenebis(4-ethyl-6-(1-methylcyclohexyl)phenol; 4,4 '-butylidenebis(6-tert-butyl-3-methylphenol); 4,4'-thiobis(6-tert-butyl-3-methylphenol); 4,4'-methylenebis(2,6-dimethylphenol); 1,1'-thiobis(2-naphthol); 2,2'-thiobis(4-methyl-6-tert-butylphenol); 2,2'-isobutylidenebis(4,6-dimethylphenol), and 2,2'-methylenebis(4-methyl-6-cyclohexyl)phenol).
Preferred metathesis catalyst precursors include W(NC6 H5) (CH2 CMe3)4, W(NC6 H5) (CH2 SiMe3)4, W(NC6 H5) (CH2 SiMe3)3 Cl , WO(CH2 CMe3)4, WO(OCH2 CMe3)2 (CH2 CMe3)2, WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OC6 H3 -2,6-i-Pr2)3 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OC6 H3 -2,6-i-Pr2)2 (CH2 CMe2 Ph)2, W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe3)2, W(NC6 H5) (OCMe3)2 (CH2 CMe3)2, W(NC6 H3 -2,6-i-Pr2) (OC6 H3 -2,6-i-Pr2)2 (CH2 CMe3)2, Mo(NC6 H3 -2,6-i-Pr2) (OCH(CF3)2)2 (CH2 CMe3)2, Mo(NC6 H3 -2,6-i-Pr2) (OCH(CF3)2)2 (CH2 CMe3)2 (NH2 CMe3), Mo(NC6 H3 -2,6-i-Pr2) (OCH(CF3)2)2 (CH2 CMe2 Ph)2, Mo(NC6 H3 -2,6-i-Pr2) (OC6 F5)2 (CH2 CMe2 Ph)2 (NH2 CMe3), Mo(NC6 H3 -2,6-i-Pr2) (OC6 F5)2 (CH2 CMe3)2 (NH2 CMe3), Mo(NCMe3) (OC6 F5)2 (CH2 CMe3)2 (NH2 CMe3), W(NC6 H3 -2,6-i-Pr2)Cl2 (norbornyl)2, WO(OC6 H3 -2,6-i-Pr2)Cl2 (dicyclopentenyl)2, WO(OC6 H3 -2,6-Cl2)Cl2 (dicyclopentenyl)2 and WO(OC6 H3 -2,6-i-Pr2)3 (CH3), where Me is a methyl group, Ph is a phenyl group, and i-Pr is an isopropyl group.
A preferred method for preparing catalyst precursors of the type M(Y)(OR2)2 (R3)2 is to react M(Y)(OR2)4 with two equivalents of an alkylating agent containing R3 groups, preferably in an inert atmosphere. Suitable alkylating agents include alkyl lithiums (R3 Li); Grignard reagents (R3 MgCl), dialkylmagnesiums ((R3)2 Mg), and dialkylzincs ((R3)2 Zn). Most preferred are Grignard reagents for example, neopentylmagnesium chloride and neophylmagnesium chloride. A Lewis base can optionally be present in the reaction mixture.
As an example of the synthesis described above, tungsten (VI) oxytetrachloride-based catalyst precursors, e.g., WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2, can be prepared by reacting WO(OCH2 CMe3)4 (generated from WOCl4 and neopentanol) with neophylmagnesium Grignard. Fewer side reactions occur compared to prior synthesis methods where WO(OCH2 CMe3)2 Cl2 is reacted with an alkylating agent, e.g., RMgX, and a much higher yield of pure product is therefore achieved. This route can be employed when using chelating ligand groups such as W(Y)(O--O)(OR)2, and when tungsten-imido complexes are desired. For example, W(NR1) (OR2)2 (R3)2 is prepared by reacting W(NR1) (OR2)4 with R3 MgCl.
In addition, the present invention also encompasses within its scope a novel preparative method for one particular class of catalysts capable of metathesizing an olefin, the catalysts having the formula:
M(═CHR4) (NR1)(OR2)2 Ls (II)
wherein M is molybdenum or tungsten; R1 and R2 are the same or different and are selected from alkyl, cycloalkyl, cycloalkenyl, polycycloalkyl, polycycloalkenyl, haloalkyl, haloaralkyl, substituted or unsubstituted aryl and aralkyl groups, or silicon-containing analogs thereof; R4 is an alkyl, aryl, or aralkyl group; L is a Lewis base, and s is 0 or 1.
R1 is preferably selected from ethyl, tert-butyl, perfluoro-2-methyl-2-pentyl, 1-adamantyl, phenyl, 2,6-dimethylphenyl, 2,4,6-trimethylphenyl, pentafluorophenyl, tri-tert-butylsilyl, triphenylmethyl, triphenylsilyl, 2,6-diisopropylphenyl, 2,6-dichlorophenyl, and 2-tert-butyl phenyl groups.
R2 is preferably selected from tert-butyl, trifluoro-tert-butyl ((CF3) (CH3)2 C), hexafluoro-tert-butyl ((CF3)2 (CH3)C), perfluoro-tert-butyl ((CF3)3 C), neopentyl (CH2 CMe3) , neophyl (CH2 CMe2 Ph, where Ph=phenyl), perfluoro-2-methyl-2-pentyl, 2,6-dimethylphenyl, 2,6-diphenylphenyl, 2,4,6-trimethylphenyl, pentafluorophenyl, trimethylsilyl, tri-tert-butylsilyl, triphenylsilyl, 2,6-diisopropylphenyl, and 2,6-dichlorophenyl groups.
R4 is preferably hydrogen or a phenyl (C6 H5), tert-butyl (CMe3), dimethylphenylmethyl (Me2 PhC), or trimethylsilyl (Me3 Si) group. If the catalyst generation is performed in an olefin metathesizable monomer, R4 can also represent any substituent that results from the initial reaction between the M═CHR4 complex and the olefin that is being metathesized. When R3 is a cycloalkyl, polycycloalkyl, cycloalkenyl, or polycycloalkenyl group, then (═CHR4) can be replaced by (═CRR'), where R and R' are hydrocarbon groups and together can form a cyclic structure. For example, a bis(cyclopentyl) complex generates a cyclopentylidene moiety.
The compounds (II) can be prepared by supplying energy to a mixture of (1) the catalyst precursor (I) where z is 0; and (2) a solvent, a metathesizable olefin, or a mixture of the two. An intramolecular reaction occurs in solution to yield M(═CHR4)(NR1)(OR2)2 Ls. The most preferred source of energy for activating compound (I) is heat. However, laser, sound or microwave radiation can also be used. The most preferred groups are W and Mo for M; CH2 CMe3, CH2 CMe2 Ph, CMe(CF3)2 and C(CF3)3 for R2, and neopentyl, neophyl, or trimethylsilylmethyl for R3.
Transformation of the catalyst precursor (I) to an active metathesis catalyst can be performed over a wide range of temperatures. The reaction can be conducted from about -78°C to about 200°C, preferably from about -40°C to about 150°C, and most preferably from about 0°C to about 120°C
As an example of the synthesis described above, the highly reactive tungsten alkylidene, W(═CHCMe2 Ph)(NC6 H3 -2,6-i-Pr2)(OCMe3)2, can be prepared in a one pot, four step process starting from tungsten oxytetrachloride (WOCl4). The reaction sequence is shown in the following scheme: ##STR1##
Tungsten (VI) oxytetrachloride (WOCl4) reacts with 2,6-diisopropylphenyl isocyanate in a solvent (e.g., octane) to give W(NC6 H3 -2,6-i-Pr2)Cl4 !2. Lithium tert-butoxide (LiOCMe3) reacts with W(NC6 H3 -2,6-i-Pr2)Cl4 !2 in diethyl ether/tetrahydrofuran to yield W(NC6 H3 -2,6-i-Pr2)Cl2 (OCMe3)2 (THF). Alkylation of W(NC6 H3 -2,6-i-Pr2) Cl2 (OCMe3)2 (THF) by neophylmagnesium chloride results in the formation of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2. These synthesis steps are outlined by R. R. Schrock in Organometallics, 1990, vol. 9, pages 2262-2275. Heating a solution of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 results in the formation of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph). The reaction mixture can be filtered after thermolysis to give a solution of alkylidene. The reaction product can be retained in solution or isolated as a solid by the evaporation of volatiles from the solution using distillation techniques.
The catalyst precursor system of this invention is suitable for the metathesis of an olefin or a mixture of olefins. "Metathesis" includes simple metathesis of olefins, acyclic diene metathesis (ADMET), ring opening metathesis polymerization (ROMP), ring closure, and depolymerization reactions.
In the present invention, olefin metathesis is accomplished by combining the following ingredients and supplying energy to the mixture:
(i) at least one olefin metathesis catalyst precursor having the formula (I), and
(ii) at least one olefinic compound that is capable of adding to the alkylidene moiety generated from the olefin metathesis catalyst precursor to generate a new alkylidene substituent capable of sustaining olefin metathesis activity, e.g., norbornene.
The most preferred source of energy is heat. However, laser, sound, or microwave radiation can also be used.
When employing the catalyst precursors in ADMET chemistry, the molar ratio of monomer to metal is preferably about 50:1 to about 10,000:1, most preferably about 100:1 to about 1,000:1. In the olefin metathesis of simple olefins, such as methyl oleate and cis-2-pentene, a monomer to catalyst precursor molar ratio as low as possible is preferred, i.e., 50:1 to 500:1.
Suitable olefin metathesizable substrates include acyclic olefins, cyclic olefins, polycyclic olefins, and α,ω-diolefins. Specific examples include, for example, ethylene, cis-2-pentene, trans-2-pentene, cis-3-hexene, cis-5-decene, methyl oleate (cis-methyl-9-octadecenoate), ethyl oleate, 4-pentenyl acetate, pentadec-1-ene, dec-1-ene, 2-methylbut-2-ene, trimethylvinylsilane, allyltrimethylsilane, and styrene.
Monomers suitable for ADMET chemistry include 1,5-hexadiene, 1,9-decadiene, ethylene diundecenoate, bis(hexenyl)ether, 2,5-dihydrofuran, diallyl ether, diallyldimethylsilane, 4,4,7,7-tetramethyl-4,7-disiladeca-1,9-diene, 1,4-bis(allyldimethylsilyl)b enzene, 1,4-benzenedicarboxylic bis(1-hexenyl) ester, 1,4-benzenedicarboxylic bis (1-pentenyl) ester, 1,4-benzenedicarboxylic bis(1-butenyl) ester, and 1-hexenyl-1-pentanoate, trivinylcyclohexane, divinylcyclohexane, and 1,4-divinylbenzene.
The metathesis reaction is preferably carried out in the absence of a solvent. However, a solvent can be present. Suitable solvents include, for example, pentane, hexane, dichloromethane, methylcyclohexane, benzene, chlorobenzene, and toluene. The reaction can be conducted at about 0°C to about 200°C, preferably about 25°C to about 150°C, and most preferably about 40°C to about 120°C
Cyclic olefins can be metathesis polymerized to a high polymer yield in bulk (neat monomer) or in solution using the catalyst precursor of this invention. The metathesis polymers can be either thermoset or thermoplastic polymers. A thermoplastic polymer is one that can be repeatedly softened by heating and hardened by cooling through a temperature that is characteristic of the polymer and that in the softened state can be shaped by flow into articles by molding or extrusion. Thermoplastic polymeric molecules are linear or branched and as a rule are soluble in specific organic solvents. A thermoset polymer is one that, after having been cured by heat or by other means, is substantially infusible or insoluble. Crosslinked (or cured) polymers can be swelled by organic solvents but cannot be dissolved by them without decomposition.
Preferred cyclic olefin monomers and comonomers are those of the norbornene type that can be represented by the structural formulas ##STR2## in which each R is selected independently from hydrogen, C1-20 alkyl, C1-20 alkenyl, and aryl groups, and saturated or unsaturated cyclic hydrocarbon groups in which the R groups are linked together through carbon atoms.
Included in such monomers and comonomers are endo- and exo-dicyclopentadiene (DCPD), symmetrical and unsymmetrical trimers and tetramers of cyclopentadiene, higher order cyclopentadiene oligomers, 2-norbornene, 1-methyl-2-norbornene, 5-methyl-2-norbornene, 5,6-dimethyl-2-norbornene, 5-butyl-2-norbornene, 5-hexylnorbornene, 7-methylnorbornene, vinylnorbornene, ethylidenenorbornene, 5-(2-propenyl)-norbornene, norbornadiene, 5,8-methylene-5a,8a-dihydrofluorene, exo-trans-exopentacyclo 8.2.1.1.14,7.02,9.03,8 !tetradeca-5,1 1-diene, 5,6-acenaphthalenenorbornene, cyclohexenylnorbornene, dimethanohexahydronaphthalene, dimethanooctahydronaphthalene, alkyl substituted derivatives of these cycloolefins and mixtures thereof.
Other suitable polymerizable olefin metathesizable substrates include cyclobutene, cyclobutadiene, cyclopentene, cyclooctene, cycloheptene, cyclododecene, 1,5-cyclooctadiene, cyclododecadiene, and cyclododecatriene.
Additional suitable polymerizable olefin metathesizable substrates include those reported by R. R. Schrock et al. in Macromolecules, Vol. 24, 1991, p. 4495-4502; R. R. Schrock in Accounts of Chemical Research, Vol. 23, 1990, 158-165, and R. R. Schrock in The Strem Chemiker, Vol. XIV (No. 1) October 1992, p. 1-6 (Strem Chemicals, Inc.). Other functionalized monomers include: 2-norbornene-5-carbonitrile, 5-norborn-2-yl acetate, 5-exo-methoxycarbonylnorbornene, endo,endo-5,6-dimethoxynorbornene, 5-endo-methoxycarbonylnorbornene, endo,endo-5,6-dimethoxynorbornene, 5,6-exo-, endo-bis(methoxycarbonyl)norbornene, 5,6-exo-, exo-bis(methoxycarbonyl)norbornene, 5,6-endo-, endo-bis(methoxycarbonyl)norbornene, endo,endo-5,6-dimethoxynorbornene, endo,endo-5,6-dicarbomethoxynorbornene, 2,3-dimethoxynorbornadiene, 5,6-bis(chloromethyl)bicyclo 2.2.1!hepta-2-ene, 2,3-endo-cis-diacetoxy-7-oxanorbornene, 2,3-bistrifluoromethyl-7-oxabicyclo 2.2.1!hepta-2,5-diene, 2,3-dicarbomethoxy-7-oxabicyclo 2.2.1!hepta-2,5-diene, 7-oxa-benzonorbornadiene, 2,3-trans-dicyano-7-oxanorborn-5-ene, 5-tris(ethoxy)silylnorbornene, 2-dimethylsilylbicyclo 2.2.1!hepta-2,5-diene, 2,3-bistrifluoromethylbicyclo( 2.2.1!hepta-2,5-diene, 5-fluoro-5-pentafluoroethyl-6-,6-bis(trifluoromethyl)bicyclo 2.2.1!hept-2- ene, 5,6-difluoro-5-heptatafluoroisopropyl-6-trifluoromethyl)bicyclo 2.2.1!hept -2-ene, 2,3,3,4,4,5,5,6-octafluorotricyclo 5.2.1.0!dec-8-ene, 2,3-bis(trifluoromethyl)-7-oxabicyclo 2.2.1!-hept-2,5-diene, and 5-trifluoromethylbicyclo 2.2.1!hept-2-ene.
The monomers used should preferably be of the highest purity, containing less than 2% impurities. The endo/exo DCPD used in the following examples was about 98-99% pure monomer. Other monomers or comonomers employed in the practice of this invention should be about this degree of purity. However, the catalysts of this invention can polymerize less pure grades of olefin metathesizable monomers when the appropriate tungsten and molybdenum compounds are employed.
For simple olefin metathesis and polymerization (ADMET and ROMP) reactions performed in solution, the preferred process is to mix the olefin metathesizable species with the olefin metathesis catalyst precursor, or a mixture of catalyst precursors, in a hydrocarbon solvent. When a liquid olefin metathesizable substrate is employed, a reaction solvent may be omitted. Energy is then supplied to the olefin and olefin metathesis catalyst precursor reaction mixture to convert the catalyst precursor to an olefin metathesis catalyst, and to initiate the olefin metathesis reaction. The reaction products can be recovered by removal of the solvent, if necessary, and separation. When a solid olefin metathesizable substrate is employed, the sample can be dissolved or swollen in solvent. For a solid olefin metathesizable substrate, the process of achieving efficient olefin metathesis includes heating a physical mixture of at least one metathesizable olefin and at least one olefin metathesis catalyst precursor to their fusion temperature, or beyond, and inducing dissolution of the ingredients and metathesis of the substrate.
When appropriate olefinic monomers are employed, bulk polymerization of monomers can be carried out in the absence of solvent. By activating a mixture of at least one olefin metathesis catalyst precursor and at least one olefin metathesizable monomer, the polymerization of acyclic and cycloolefins can be achieved. The polymerization of the monomer can yield films, fibers, and molded articles.
The polymerization of the monomer can be performed in a mold to form a solid object. The polymerizable olefin/olefin metathesis catalyst precursor mixture can be introduced into the mold by injection, resin transfer molding, and pouring of liquids, or by addition as a solid. In the case of solid components, production of an olefin metathesis polymer includes supplying energy to a physical mixture of at least one metathesizable olefin and at least one olefin metathesis catalyst precursor to heat the mixture to its fusion temperature, or beyond, and inducing dissolution of the ingredients and metathesis of the reactive olefin. Typically the mold is heated to between 20° and 150° C.
The olefin metathesis catalyst precursor can be placed on a solid support prior to introduction into the mold cavity. Solid supports can include, for example, glass beads, glass fiber, molecular sieves or powder, glass mat, and carbon fiber. The unicomponent olefin metathesis catalyst precursor can be introduced as an encapsulated species, either as an encapsulated liquid or as a solid, provided that the encapsulating material dissolves when in contact with the polymerizable monomer or melts during the input of energy.
A preferred method for molding an object in a single step is injection molding. A reaction injection molding machine is preferably used for convenience. The process for forming a molded object comprising a metathesis polymer includes (1) introducing at least one olefinic metathesis polymerizable monomer and at least one metathesis catalyst precursor into a mold, (2) activating the catalyst precursor in the mold by an energy input to effect catalyst formation and metathesis polymerization to form a solid object, and (3) removing the solid molded article from the mold.
Alternatively, the generation of the olefin metathesis catalyst from the metathesis catalyst precursor can be achieved by supplying energy to a liquid stream (solvent or polymerizable monomer) of the catalyst precursor prior to the stream entering the mold. Supplying additional energy to the reaction mixture in the mold is optional.
In conventional reaction injection molding processes for dicyclopentadiene and other cycloolefins, two reactant streams, one containing an activator and one containing a conventional metathesis catalyst precursor, and at least one stream containing a polymerizable monomer, are mixed together by impingement mixing, or through a mixhead, and the resultant mixture is then introduced into a mold.
Two or more components are typically employed to form alkylidene complexes, e.g., by the reaction of a metal halide and an alkylating agent (see Klosiewicz, U.S. Pat. Nos. 4,400,340 and 4,520,181). The olefin metathesis precursor (I) of this invention can be used to improve the monomer to polymer conversions of these conventional in situ-generated catalyst systems. The olefin metathesis precursor (I) of this invention can be introduced as an extra stream into a system containing an activator and a conventional catalyst precursor, or it can be combined with either the activator or the conventional catalyst precursor. Separate streams of catalyst ingredients are preferred. For example, a stream of cycloolefin containing diethylaluminum chloride, a stream of cycloolefin containing W(NC6 H3 -2,6-i-Pr2) (OC6 H3 -2,6-i-Pr2)2 Cl2, and a stream of cycloolefin containing W(NC6 H3 2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 in either cycloolefin or solvent can be admixed at a mixhead and injected into a mold. In the case of dicyclopentadiene and similarly strained olefins, admixture of an activator and conventional catalyst precursor results in a significant exotherm capable of supplying enough energy to convert the olefin metathesis catalyst precursor (I) of this invention to an olefin metathesis catalyst. Mixtures of activators, conventional catalyst precursors, and the energy-activated olefin metathesis catalyst precursors (I) of this invention, and metathesizable monomers in two or more streams are also within the scope of this invention. Suitable activators are organoalkyl aluminums (R3 Al), organoalkylaluminum halides (R3-x AlXx), organoalkylaluminum alkoxides (R2 (RO)Al), alkylalkoxyaluminum halides (R(RO)AlX), trialkyltin hydrides (R3 SnH), triaryltin hydrides (Ar3 SnH), alkyltins (R4 Sn), aryltins (Ar4 Sn), diorganozincs (R2 Zn), and Grignard reagents (RMgX). Suitable conventional catalyst precursors are selected from those derived from tungsten hexachloride (WCl6), tungsten oxytetrachloride (WOCl4); tungsen organoimidotetrachloride (W(NR)Cl4), alkoxide and aryloxide derivatives of tungsten hexachloride (WCl6-x (OR)x), tungsten oxytetrachloride (WOCl4-x (OR)x), tungsten organoimidotetrachloride (W(NR)Cl4-x (OR)x); organoammonium molydates, and organoammonium tungstates.
A preferred embodiment of the RIM process using the catalyst precursors of this invention (I) involves the polymerization of dicyclopentadiene monomer. For example, by injecting a metathesis catalyst precursor (I)/DCPD stream into a heated mold, the formation of a tough, rigid thermoset polyDCPD (crosslinked polymer) is readily achieved. In this way, a spontaneous polymerization occurs and a polymer containing low residual monomer (<1%, preferably <0.5%) can be obtained. This process for preparing polyDCPD can be modified to use more than one stream. Mixtures of catalyst precursors and metathesis polymerizable monomers in one or more streams are also within the scope of this invention.
The molding of olefin metathesis polymerizable monomers can be achieved using a catalyst precursor to monomer molar ratio of about 100:1 to about 200,000:1 on a molar basis, preferably about 200:1 to about 20,000:1, and most preferably about 500:1 to about 5000:1. For a cycloolefin such as dicyclopentadiene, the ratio of catalyst precursor to monomer will preferably be from about 100:1 to about 200,000:1, more preferably 100:1 to 20,000:1, and most preferably about 1500:1 to about 6000:1.
The preparation of molded articles according to the present invention can be carried out in the presence of additives, such as, for example, solvents, blowing agents, fillers, fibers, pigments, antioxidants, flame retardants, light stabilizers, plasticizers, foaming agents, tougheners, reinforcing agents, and polymeric modifiers and viscosifiers. These components are most conveniently added to the reaction as constituents of one or more of the reaction mixture streams, as liquids or as solutions in the monomer.
In some embodiments of this invention, a preformed elastomer that is soluble in the reactant streams is added to the metathesis-catalyst system in order to increase the impact strength of the polymer. The elastomer is dissolved in either or both of the reactant streams in an amount from about 1 to about 15 weight percent, based on the weight of monomer. Suitable elastomers include, for example, natural rubber, butyl rubber, polyisoprene, polybutadiene, polyisobutylene, ethylene-propylene copolymer, styrene-butadiene-styrene triblock rubber, random styrene-butadiene rubber, styrene-isoprene-styrene triblock rubber, ethylene-propylene-diene terpolymers, ethylene-vinyl acetate and nitrile rubbers. Various polar elastomers can also be used. The amount of elastomer used is determined by its molecular weight and is limited by the viscosity of the resultant streams. Preformed elastomers that are essentially insoluble in the reactant streams can also be used.
When using the energy-activated catalyst precursor (I), the rate of catalyst formation depends only on the initiation temperature, therefore gel and cure times can be controlled by adjusting the polymerization temperature. As the temperature at which the reaction is carried out is increased, the gel and cure times will decrease.
The use of Lewis base rate moderators in this system is optional, resulting in further gel and cure time control. Suitable rate moderators include, for example, tetrahydrofuran (THF), 2-methyltetrahydrofuran (2-Me-THF), diethyl ether ((C2 H5)2 O), dimethoxyethane (CH3 OCH2 CH2 OCH3), trimethylphosphine (PMe3) triethylphosphine (PEt3), tributylphosphine (PBu3), tricyclohexylphosphine (PCy3), triphenylphosphine (PPh3), methyldiphenylphosphine (PMePh2), dimethylphenylphosphine (PMe2 Ph), trimethyl phosphite (P(OMe)3), triethyl phosphite (P(OEt)3), triisopropyl phosphite (P(O-i-Pr)3), ethyl diphenylphosphinite (P(OEt)Ph2), tributyl phosphite (P(OBu)3), triphenyl phosphite (P(OPh)3), triisopropylphosphine (P-i-Pr3), tri-tert-butylphosphine (P-tert-Bu3), diethyl phenylphosphonite (P(OEt)2 Ph), tribenzylphosphine (P(CH2 Ph)3), tert-butylamine, pyridine, pyrazine, and quinuclidine. Chelating phosphorus ligands, (R)2 P(CH2)n P(R)2, where n≧1 and R=aryl or alkyl, can also be employed.
Olefin metathesis thermoset and thermoplastic polymers can be prepared using the activated catalyst precursors of this invention by RIM or other polymerization processes. These polymers contain only trace levels of inorganic halogen or are free of inorganic halogen, e.g., choride ion. Metathesis polymers of dicyclopentadiene comprised of greater than or equal to 80% metathesis-catalyzed, polymerized units of dicyclopentadiene have only trace levels of inorganic halogen. A trace level of a halogen element is regarded as values of less than 25 ppm.
In the examples in which polymerization studies are set forth, the following general procedures were followed. All operations were carried out under a dry nitrogen or argon atmosphere or in vacuum either in a Vacuum/Atmospheres HE-43 Dri-Lab fitted with a HE-493 Dri-Train or its equivalent (available from Vacuum/Atmospheres Company, Hawthorne, Calif. U.S.A.) or using Schlenk techniques. Schlenk techniques are described in The Manipulation of Air-Sensitive Compounds, 2nd Edition, D. F. Schriver & M. A. Drezdzon, John Wiley and Sons, Inc., New York, 1986. All liquid transfers must be performed by cannula or syringe to maintain an inert atmosphere. Dicyclopentadiene (DCPD) (98-99%) was used in the polymerization experiments.
Polymerizations were conducted in argon- or nitrogen-flushed test tubes, serum vials, glass bottles, reaction vessels or other molds. In general, the polymerizations were accomplished by adding the catalyst precursor, either in solution or in DCPD, to the activator in dicyclopentadiene. Mixing of the ingredients was accomplished with a vortex mixer, magnetic stirrer, or mechanically. The reaction mixtures were maintained at ambient temperature or placed in a constant temperature bath at 80°C or higher. Gel times (tgel) were estimated by observing the initial viscosity change where the mixture changed from a flowable to a nonflowable mass. The time (t100°C or t180°C) was recorded when the polymerization raised the exotherm to 100°C or 180°C (depending on the initial temperature of the solution), and to the maximum temperature (tTmax) of the polymerization. The maximum temperature (Tmax) of the polymerization was also recorded. The residual DCPD level in polyDCPD samples was obtained by swelling the sample in toluene to extract the DCPD and determining the amount of unreacted DCPD by gas chromatography using an internal standard of dodecane.
In addition to measuring gel and cure times and residual monomer level in the following examples, a measurement of swell value was made. The swell value is an indication of the degree of crosslinking in the polymer, i.e., lower swell values indicate a higher degree of crosslinking. The swell value was determined by removing a sample of polymer from its polymerization vessel and carefully cutting it into smaller pieces. Burrs were removed, and each piece was weighed to the nearest milligram. The samples were then placed in a volume of toluene (50 ml of toluene for each gram of polymer), heated to reflux for 16 hours (overnight) and cooled. After this time, each sample was removed from the flask and placed in a small dish of fresh toluene. The slices were removed, patted dry, and weighed individually. The swell values were calculated using the following formula: swell (%)=(w2 -w1)/w1 ×100%, where w1 =the initial weight of the polyDCPD sample and w2 =the weight of the solvent-swollen polyDCPD sample. Since the swell value is an indication of the degree of crosslinking in the polymer, low values are preferred.
This example describes the preparation of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2, where i-Pr is an isopropyl group, Me is a methyl group, and Ph is a phenyl group.
A prechilled (-38° to -45°C) diethyl ether solution of neophylmagnesium chloride (0.077 moles) was added rapidly by drops over a 15 minute period to a chilled solution (-38° to -45°C) of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 Cl2.THF (50.07 g, 0.154 moles) in 160 ml of diethyl ether, where THF is tetrahydrofuran. The reaction mixture was stirred at room temperature for 24 hours. The salts were removed from the orange solution by centrifuging, then filtering through Manville Celite® filter-aid (available from Fisher Scientific, Fair Lawn, N.J., U.S.A.) and the filter cake was washed thoroughly with diethyl ether (4×50 ml). An orange solid formed upon concentrating the solution in vacuo. The solids were collected and recrystallized from pentane as bright red-orange crystals. A single crystal X-ray determination was performed on the sample and it was found to be pseudo-square pyramidal in geometry with neophyl and tert-butyl groups disposed in a trans geometry.
This example describes the preparation of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe3)2.
A prechilled (-40°C) diethyl ether solution of neopentylmagnesium chloride (33.7×10-3 moles) was added by drops to a chilled solution (-40°C) of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 Cl2.THF (10.07 g, 15.53×10-3 moles) in 100 ml of diethyl ether, where THF is tetrahydrofuran. The reaction mixture was stirred at room temperature for 60 hours. The solution was evaporated to dryness and the product was removed from the salts by washing the solids thoroughly with diethyl ether and pentane. Successive recrystallization from the original pentane/diethyl ether solution yielded 6.16 g of a yellow orange W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe3)2 product.
This example describes the preparation of WO(OCH2 CMe3)2 (CH2 CMe3)2.
WO(OCH2 CMe3)2 Cl2 was reacted with two molar equivalents of neopentylmagnesium chloride (Me3 CCH2 MgCl) in diethyl ether at -78°C Pure WO(OCH2 CMe3)2 (CH2 CMe3)2 was isolated by recrystallization from pentane at -78°C
This example describes the preparation of WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2.
WO(OCH2 CMe3)4 was reacted with two molar equivalents of neophylmagnesium chloride (PhMe2 CCH2 MgCl) in diethyl ether at -78°C Pure WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2 was isolated from the crude reaction product by recrystallization from cold pentane.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.015 g in 0.3 ml of toluene) was mixed with 5 ml of dicyclopentadiene in a glass test tube. The DCPD:W molar ratio was 2000:1. After mixing the reagents briefly at room temperature, the reaction mixture was heated in a 80°C oil bath. The following reaction parameters describe the polymerization experiment: tgel =18 seconds; t100°C =39 seconds; t180°C =42 seconds; tTmax =56 seconds; and Tmax =203°C Residual DCPD =0.38%.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.113 g in 0.4 ml of toluene) was mixed with 100 ml of dicyclopentadiene containing 3 wt % ethylidenenorbornene in a glass bottle. The DCPD:W molar ratio was 2000:1. After mixing the reagents at room temperature for five minutes, the bottle and reaction contents were heated to 80°C At 14 minutes the reaction mixture was a thick gel. At 21 minutes and 30 seconds the dicyclopentadiene solution had polymerized to a solid block, and the internal temperature was 221° C.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.113 g in 0.4 ml of toluene) was mixed with 100 ml of dicyclopentadiene containing 3 wt % ethylidenenorbornene in a glass bottle. The DCPD:W molar ratio was 5000:1. After mixing the reagents at room temperature for five minutes, the bottle and reaction contents were heated to 80°C At 14 minutes the reaction mixture was a thick gel. At 21 minutes and 30 seconds the dicyclopentadiene solution had polymerized to a solid block, and the internal temperature was 221° C.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.057 g in 0.4 ml of toluene) was mixed with 100 ml of dicyclopentadiene containing 3 wt % ethylidenenorbornene in a glass bottle. The DCPD:W molar ratio was 10,000:1. After mixing the sample, the bottle and reaction contents were heated to 80°C After 14 minutes the dicyclopentadiene solution had polymerized to a solid block, and the internal temperature was 213°C
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.057 g in 0.4 ml of toluene) was mixed with 100 ml of dicyclopentadiene containing 3 wt % ethylidenenorbornene in a glass bottle. The DCPD:W molar ratio was 10,000:1. After mixing the reaction contents, the mixture was kept at room temperature for 4 hours. No polymerization exotherm was observed. The sample was then heated to 80°C After 17.5 minutes the dicyclopentadiene solution had polymerized to a solid block, and the internal temperature was 193° C.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.028 g in 0.4 ml of toluene) was mixed with 100 ml of dicyclopentadiene containing 3 wt % ethylidenenorbornene in a glass bottle. The DCPD:W molar ratio was 20,000:1. After mixing the sample for five minutes at room temperature, the bottle and reaction contents were heated to 80°C At 16.5 minutes the dicyclopentadiene solution had polymerized to a solid block, and the internal temperature 205°C
This example describes the preparation of a chlorine-free dicyclopentadiene polymer using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0.028 g in 0.4 ml of toluene) was mixed with 100 ml of dicyclopentadiene containing 3 wt % ethylidenenorbornene in a glass bottle. The DCPD:W molar ratio was 20,000:1. After mixing the sample for five minutes at room temperature, the bottle and reaction contents were heated to 80°C At 16.5 minutes the dicyclopentadiene solution had polymerized to a solid block, and the internal temperature was 205° C. When analyzed for chlorine content, the polyDCPD was found to contain 22 ppm. This amount of chlorine is regarded as a trace level of the element and, based on the fact that no chlorine was introduced into the ingredients, this level is regarded as contamination through incidental contact.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor and a Lewis base reaction rate moderator.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (0∅10 g in 0.4 ml of toluene) was mixed with 10 ml of dicyclopentadiene in a glass test tube. The DCPD:W molar ratio was 2000:1. To this mixture was added triethylphosphine (Et3 P) (2 eq. per W). After mixing the reagents at room temperature, the reaction contents were heated to 80°C After 7 seconds the reaction mixture gelled. The polymerization mixture reached 100°C at 3 minutes 55 seconds and 180°C at 4 minutes 12 seconds. After 4 minutes and 44 seconds the dicyclopentadiene solution had polymerized to a solid block and the maximum internal temperature was 224°C
This example describes the preparation of polydicyclopentadiene plaques by reaction injection molding, using W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
Using a laboratory scale RIM molding machine, polydicyclopentadiene plaques were made by feeding equal volumes of two streams of DCPD monomer (>98% purity containing 3% ethylidenenorbornene (ENB) as a freezing point depressant) to a mixhead and immediately injecting the catalyst mixture into a heated mold. One stream contained only DCPD and the second contained the catalyst precursor W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 (2.52 g) dissolved in DCPD (865 g DCPD, 3 wt % ENB). The DCPD:W molar ratio was 2000:1. The mixing and mold filling were accomplished within two seconds. The rate of polymerization was determined by the mold temperature as shown in Table 1.
TABLE 1 |
______________________________________ |
Effect of Temperature on Cure Times (tTmax) |
Molding Residual |
Temperature Cure Time Monomer |
(°C.) (seconds) (%) |
______________________________________ |
90 108 1.01 |
92 -- 1.35 |
107 74 2.01 |
114 43 1.46 |
135 38 5.54 |
______________________________________ |
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) at 60°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 60°C and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) at 70°C
W(NC6 H3 -2, 6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 70°C and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) at 80°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 80°C and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) at 90°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 90°C and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) at 100°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 100°C and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe3)2 to W (NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe3) at 80°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe3)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 80°C and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe3) and neopentane.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe3)2 to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe3) at 90°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2)2 (50 mg) was dissolved in d8 -toluene (1 ml). The solution was heated to 90°C and the reaction was monitored by proton NMR spectroscopy. The sample was seen to cleanly convert to W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe3) and neopentane.
This example describes the conversion of W(NC6 H3 -2,6-i-Pr2) (OC(CF3)3)2 (CH2 CMe2 Ph)2 to W(NC6 H3 -2,6-i-Pr2) (OC(CF3)3)2 (═CHCMe2 Ph) at 80°C
W(NC6 H3 -2,6-i-Pr2) (OC(CF3)2)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d8 -toluene (1 ml) and heated to 80°C in an oil bath for one hour. The proton NMR spectrum contained tungsten alkylidene resonances attributable to W(NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2 (═CHCMe2 Ph).
This example describes the preparation of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) from W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 at 70°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (2.82 g) was placed a Schlenk tube and dissolved in hexane (75 ml). The reaction mixture was heated to 70°C for 4 hours, during which time the solution color changed slightly from red-orange to red-brown. The mixture was stripped of hexane and tert-butylbenzene to recover the reaction product. The proton NMR spectrum of this reaction product showed essentially pure W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph). This was confirmed by comparing the spectrum to one obtained for a sample of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph) prepared from W(NC6 H3 -2,6-i-Pr2)(═CHCMe2 Ph)Cl2 (DME) and two equivalents of lithium tert-butoxide following the method described in R. R. Schrock et al., Organometallics 1990, Volume 9, pages 2262-2275.
This example describes the preparation of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) from W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 at 80°C
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (3.93 g) was placed in a Schlenk tube and dissolved in toluene (50 ml). The reaction mixture was heated to 80°C for 2 hours, during which time the solution color changed slightly from red-orange to orange-yellow. The mixture was stripped of solvent to recover a crude reaction product (3.27 g; 100% yield). The proton NMR spectrum of this reaction product showed essentially pure W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph). The solids were recrystallized from pentane at -40° to -50°C to yield W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) as a yellow powder (1.76 g; 55.7% yield). The identity of this complex was confirmed by comparing the spectrum to one obtained for a sample of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) prepared as described in R. R. Schrock et al., Organometallics 1990, Volume 9, pages 2262-2275.
This example describes the polymerization of DCPD using WO(OCH2 CMe3)2 (CH2 CMe3)2 as the catalyst precursor.
WO(OCH2 CMe3)2 (CH2 CMe3)2 (0.016 g) was placed in a polymerization tube. Dicyclopentadiene (5 ml) was added to achieve a DCPD:W molar ratio of 1050:1. The reaction vessel was then heated to 100°C and the polymerization reaction was monitored. The following parameters describe the reaction: tgel =56 seconds; t100°C =75 seconds; t180°C =160 seconds; tTmax =182 seconds; and Tmax =236°C Residual DCPD monomer level =1.99%.
This example describes the polymerization of DCPD using WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2 (0.023 g) was placed in a polymerization tube. Dicyclopentadiene (5 ml) was added to achieve a DCPD:W molar ratio of 1000:1. The reaction vessel was then heated to 100°C and the polymerization reaction was monitored. The following parameters describe the reaction: tgel =135 seconds; t180°C =343 seconds; tTmax =364 seconds; and Tmax =223°C The residual DCPD monomer was 0.39%.
This example describes the preparation of chlorine-free dicyclopentadiene polymer using WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
WO(OCH2 CMe3)2 (CH2 CMe2 Ph)2 (0.023 g) was placed in a polymerization tube. Dicyclopentadiene (5 ml) was added to achieve a DCPD:W molar ratio of 1000:1. The reaction vessel was then heated to 100°C to initiate polymerization. When analyzed for chlorine content, the polyDCPD was found to contain 18 ppm. This amount of chlorine is regarded as a trace level of the element. Since no chlorine was introduced into the ingredients, this level is regarded as incidental.
This example describes the polymerization of dicyclopentadiene using W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was heated in d8 -toluene (0.75 g) for 2 hours at 70°-72°C to generate W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph). The composition of this sample was determined by proton NMR spectroscopy to be predominantly W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene, with only a trace of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2. This sample was evaporated to dryness, then redissolved in a minimal amount of toluene. The catalyst concentrate was injected into DCPD (17.8 ml) to give a molar ratio of DCPD:W of 2000:1. The following reaction parameters describe the polymerization experiment performed at room temperature (20°C): tgel =7 seconds; t100°C =69 seconds; t180°C =71 seconds; t200°C =67 seconds; Tmax =220°C; and tTmax =107 seconds. The residual DCPD level was 0.12%.
This example describes the preparation of W(NC6 H3 -2,6-i-Pr2) (OCMe(CF3)2)2 (═CHCMe2 Ph) from W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2.
W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (CH2 CMe2 Ph)2 (50 mg) was dissolved in d6 -benzene (1 ml). The sample was heated to 70°C for two hours and the reaction was monitored by proton NMR spectroscopy. The sample converted cleanly to W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph) and tert-butylbenzene. The sample was characterized by a resonance at δ=8.11 ppm for the alkylidene proton, W--CHCMe2 Ph. Two equivalents of hexafluoromethylisopropanol were added to this sample. Displacement of the tert-butoxide groups was monitored by the appearance of a new alkylidene signal at δ=8.92 ppm, corresponding to the newly formed W(NC6 H3 -2,6-i-Pr2)(OCMe(CF3)2)2 (═CHCMe2 Ph). The identity of this complex was confirmed by comparing the spectrum to one obtained for a sample of W(NC6 H3 -2,6-i-Pr2)(OCMe(CF3)2)2 (═CHCMe2 Ph) prepared as described in R. R. Schrock et al., Organometallics, 1990, Volume 9, pages 2262-2275.
This example describes the polymerization of 5,5,6-trifluoro-6-trifluoromethylnorbornene using in situ generated W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph) as the catalyst.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph) was generated by heating 50 mg of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 in toluene. This catalyst was injected into 5,5,6-trifluoro-6-trifluromethylnorbornene (4 ml). The reaction mixture corresponds to a DCPD:W molar ratio of 500:1. The reaction was monitored at room temperature (32°C). After a few minutes, the pale yellow liquid contained strings of polymer. The reaction was left at room temperature overnight in an inert atmosphere drybox. Addition of methanol to the monomer solution resulted in the deposition of a small quantity of white polymer.
This example describes the polymerization of 5,5,6-trifluoro-6-trifluoromethylnorbornene using in situ generated W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph) as the catalyst.
W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (═CHCMe2 Ph) was generated by heating 50 mg of W(NC6 H3 -2,6-i-Pr2)(OCMe3)2 (CH2 CMe2 Ph)2 in toluene. This catalyst was injected into 5,5,6-trifluoro-6-trifluromethylnorbornene (4 ml). This reaction mixture corresponds to a DCPD:W molar ratio of 500:1. The reaction mixture was then placed in a constant temperature bath at 80°C After a few minutes, the pale yellow liquid had become opaque and contained strings of polymer. The reaction was heated at 80°C for twelve hours, after which time a solid orange plug had formed.
This example describes the polymerization of tricyclopentadiene using W(O)(OCH2 CMe3)2 (CH2 CMe2 Ph)2 as the catalyst precursor.
W(O)(OCH2 CMe3)2 (CH2 CMe2 Ph)2 (16 mg) was dissolved in a sample of tricyclopentadiene (5.00 g) by warming the sample to the melting point of the cycloolefin. The catalyst precursor to tricyclopentadiene molar ratio was 1:1000. The catalyst precursor dissolved in the monomer within one minute. The solution was heated to 100°C to induce polymerization. The sample gelled at 163 seconds at 100°C, reached an internal temperature of 180°C at 630 seconds, and reached a maximum temperature of 196°C Residual tricyclopentadiene was 2.3%, measured by toluene extraction.
This example describes the storage of a catalyst precursor/tricyclopentadiene mixture and its subsequent polymerization.
W(O)(OCH2 CMe3)2 (CH2 CMe2 Ph)2 (16 mg) was dissolved in tricyclopentadiene (5.00 g) by warming to the melting point of the cycloolefin. The catalyst precursor to tricyclopentadiene molar ratio was 1:1000. The catalyst precursor dissolved in the monomer within one minute. The sample was then allowed to solidify at room temperature and was stored for at least sixteen hours under nitrogen. This sample was then heated to 100°C to melt the fused material and induce polymerization. The sample slowly thawed and reached the gelled state at 352 seconds, an internal temperature of 180°C at 647 seconds, and a maximum temperature of 214°C at 663 seconds. Residual tricyclopentadiene was 4.3% measured by toluene extraction.
This example describes the preparation of WOCl2 ((OC6 H2 -4-Me-6-CMe3)2 CH2).
One equivalent of 2,2'-methylenebis(4-methyl-6-tert-butylphenol) (4.98 g, 14.63 mmol) was added to a quantity of WOCl4 (5.0 g, 14.63 mmol) slurried in dried toluene (100 ml). The reaction mixture was sparged to remove the liberated HCl gas. Once the reaction had subsided, the reaction mixture was heated at reflux for one hour. The reaction mixture was then cooled to room temperature and filtered to yield a dark green powder of WOCl2 ((OC6 H2 -4-Me-6-CMe3)2 CH2). The product was characterized by proton and carbon NMR spectroscopies and by cyclic voltammetry.
This material describes the preparation of WO((OC6 H2 -4-Me-6-CMe3)2 CH2)(CH3)2.
Two equivalents of methylmagnesium chloride (MeMgCl) were added to a sample of WOCl4 dissolved in diethyl ether, and the mixture was cooled to -78°C The reaction mixture was warmed slowly to room temperature, during which time the mixture turned from green-black to dark red. The reaction product was then evaporated to dryness. The solids were extracted with copious amounts of pentane. The reaction mixture was filtered to give a blood red pentane solution of WO((OC6 H2 -4-Me-6-CMe3)2 CH2)(CH3)2 as well as magnesium salts and other insoluble reaction byproducts. The reaction product WO((OC6 H2 -4-Me-6-CMe3)2 CH2)(CH3)2 was obtained by evaporation of the pentane. The red solid was characterized by proton and carbon-13 NMR spectroscopies and cyclic voltammetry.
This example describes the polymerization of DCPD using WO((OC6 H2 -4-Me-6-CMe3)2 CH2)(CH3)2 as the catalyst precursor.
A quantity of WO((OC6 H2 -4-Me-6-CMe3)2 CH2)(CH3)2 dissolved in a minimum of dried toluene was added to a volume of DCPD (10 ml). The reactant stoichiometry was DCPD:W=1000:1 on a molar basis. The sample was heated from room temperature to 80°C The reaction mixture slowly gelled and polymerized, giving a maximum exotherm of 143°C, and a rubbery red colored plug of polyDCPD.
This example describes the polymerization of dicyclopentadiene using pure W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) as the catalyst.
The catalyst W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) was prepared according to the synthesis given for W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) in R. R. Schrock et al., Organometallics, 1990, Vol. 9, p. 2262-2275.
At 30°C, a toluene solution of W(NC6 H3 -2,6-i-Pr2) (OCMe3)2 (═CHCMe2 Ph) (0.023 g in a minimum amount of solvent) was added to a volume of dicyclopentadiene (10 ml). The following parameters describe the polymerization reaction: tgel =16 seconds, t100°C =66 seconds, t180°C =76 seconds, tTmax =108 seconds, and Tmax =217°C Residual DCPD =0.10%.
It is understood that the preceding examples are presented for illustrative purposes only and do not in any sense limit the scope of the invention as defined by the appended claims.
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