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Definitions

• thermoplastic elastomer compositions comprised of branched olefin copolymers having crystallizable polyolefin sidechains incorporated into low crystallinity polyethylene backbones.
• Triblock and multi-block copolymers are well-known in the art relating to elastomeric polymers useful as thermoplastic elastomer (“TPE") compositions due to the presence of "soft" (elastomeric) blocks connecting "hard” (crystallizable or glassy) blocks.
• TPE thermoplastic elastomer
• the hard blocks bind the polymer network together at typical use temperatures. However, when heated above the melt temperature or glass transition temperature of the hard block, the polymer flows readily exhibiting thermoplastic behavior. See, for example, G. Holden and N.R. Legge, Thermoplastic Elastomers: A Comprehensive Review, Oxford University Press (1987).
• TPE polymers are the styrenic block copolymers (SBC), typically linear triblock polymers such as styrene- isoprene-styrene and styrene-butadiene-styrene, the latter of which when hydrogenated become essentially styrene-(ethylene-butene)-styrene block copolymers.
• SBC styrenic block copolymers
• SBC typically linear triblock polymers such as styrene- isoprene-styrene and styrene-butadiene-styrene, the latter of which when hydrogenated become essentially styrene-(ethylene-butene)-styrene block copolymers.
• Radial and star branched SBC copolymers are also well-known. These copolymers typically are prepared by sequential anionic polymerization or by chemical coupling of linear diblock copolymers.
• the glass transition temperature (T Tre) of the typical SBC TPE is equal to or less than about 80-90°C, thus presenting a limitation on the utility of these copolymers under higher temperature use conditions.
• TPE polymers from olefinically unsaturated monomers such as ethylene and C 3 -C 8 ⁇ - olefins
• TPO thermoplastic olefins
• Examples include the physical blends of thermoplastic olefins ("TPO") such as polypropylene with ethylene-propylene copolymers, and similar blends wherein the ethylene- propylene, or ethylene-propylene-diolefin phase is dynamically vulcanized so as to maintain well dispersed, discrete soft phase particles in a polypropylene matrix.
• thermoplastic elastomer compounds comprising tapered and block linear polymers from ethylene and alpha-olefin monomers. Polymers having hard and soft segments are said to be possible with single site metallocene catalysts that are capable of preparing both segments. Examples are provided of linear thermoplastic elastomers having hard blocks of high density polyethylene or isotactic polypropylene and soft blocks of ethylene-propylene rubber.
• Japanese Early Publication H4-337308(1992) describes what is said to be a polyolefin copolymer product made by polymerizing propylene first so as to form an isotactic polypropylene and then copolymerizing the polypropylene with ethylene and propylene, both polymerizations in the presence of an organoaluminum compound and a silicon-bridged, biscyclopentadienyl zirconium dihalide compound.
• 4,999,403 describes similar graft copolymer compounds where functional groups in the EPR backbone are used for grafting isotactic polypropylene having reactive groups. In both the graft copolymers are said to be useful as compatibilizer compounds for blends of isotactic polypropylene and ethylene-propylene rubber.
• thermoplastic elastomer composition comprising a branched olefin copolymer derived from olefinically unsaturated monomers capable of insertion polymerization having A) a T g as measured by DSC less than or equal to 10°C; B) a melt temperature (T m ) greater than 80°C; C) an elongation at break of greater than or equal to 300%, preferably greater than 500%; D) a
• the branched olefin copolymer is one that comprises crystallizable sidechains derived from olefins, optionally with one or more copolymerizable monomers, such that the T m is greater than 80°C, and the number-average molecular weight (M n ) is greater than 1,500 and less than 45,000.
• thermoplastic elastomer composition can be prepared by the process comprising: A) copolymerizing an olefin, optionally with one or more copolymerizable monomers, in a polymerization reaction under conditions sufficient to form crystallizable or glassy copolymer having greater than 40% chain end-group unsaturation; B) copolymerizing the product of A) with ethylene and one or more copolymerizable monomers so as to prepare said branched olefin copolymer.
• This thermoplastic elastomer composition exhibits elastic properties comparable or superior to those of the traditionally important SBC copolymers thus providing alternative means of feedstock sourcing and industrial production for this important class of commercial products.
• Fig. 1 illustrates a comparison of measured physical properties of branched olefin copolymers of the invention with a commercially available styrene block copolymer thermoplastic elastomer.
• thermoplastic elastomer compositions of this invention are comprised of branched copolymers wherein both the copolymer backbone and polymeric sidechains are derived from monoolefins polymerized under coordination or insertion conditions with activated transition metal organometallic catalyst compounds.
• the sidechains are copolymerized so as to exhibit crystalline, semi- crystalline, or glassy properties suitable for hard phase domains in accordance with the art understood meaning of those terms, and are attached to a polymeric backbone that is less crystalline or glassy than the sidechains, preferably, substantially amorphous, so as to be suitable for the complementary soft phase domains characteristic of thermoplastic elastomer compositions.
• the crystallizable sidechains are comprised of chemical units capable of forming crystalline or glassy polymeric segments under conditions of insertion polymerization.
• Known monomers meeting this criteria are ethylene, propylene, 3 -methyl- 1-pentene, and copolymers thereof, including ethylene copolymers with ⁇ -olefin, cyclic olefin or styrenic comonomers.
• Ethylene or propylene copolymer sidechains are preferable provided that the amount of comonomer is insufficient to disrupt the crystallinity such that the T m is reduced below 80°C.
• Suitable comonomers include C 3 -C 20 ⁇ -olefins or geminally disubstituted monomers, C 5 - C 25 cyclic olefins, styrenic olefins and lower carbon number (C 3 -C 8 ) alkyl- substituted analogs of the cyclic and styrenic olefins.
• the sidechains can comprise from 85-100 mol% ethylene, and from 0-15 mol% comonomer, preferably 90 -99 mol% ethylene and 1-10 mol% comonomer, most preferably 94 -98 mol% ethylene and 2-6 mol% compnomer.
• the sidechains can comprise from 90-100 mol% propylene, and from 0-10 mol% comonomer, preferably 92-99 mol% propylene and 1-8 mol% comonomer, most preferably 95-98 mol% propylene and 2-5 mol% comonomer.
• the sidechain M n increases above about 3,000, it is preferable to introduce small amounts of comonomer to minimize embrittlement, e.g., about 0.2 - 4.0 mol.% comonomer.
• comonomer can be based upon properties other than crystallinity disrupting capability, for instance, a longer olefin comonomer, such as 1-octene, may be preferred over a shorter olefin such as 1-butene for improved polyethylene film tear.
• a cyclic comonomer such as norbornene or alkyl-substituted norbornene may be preferred over an ⁇ -olefin.
• the sidechains can have narrow or broad molecular weight distribution
• the sidechains can have different comonomer compositions, e.g., including the orthogonal compositional distributions described in U.S. patent 5,382,630 (CDBI >50%), incorporated by reference for purposes of U. S. patent practice.
• CDBI orthogonal compositional distributions described in U.S. patent 5,382,630
• mixtures of sidechains with different molecular weights and/or compositions may be used.
• the M n of the sidechains are within the range of from greater than or equal to 1,500 and less than or equal to 45,000.
• the M n of the sidechains is from 1,500 to 30,000, and more preferably the M n is from 1,500 to 25,000.
• the number of sidechains is related to the M n of the sidechains such that the total weight ratio of the weight of the sidechains to the total weight of the polymeric backbone segments between and outside the incorporated sidechains is less than
• Molecular weight here is determined by gel permeation chromatography (GPC) and differential refractive index (DRI) measurements.
• GPC gel permeation chromatography
• DRI differential refractive index
• a preferred branched olefinic copolymer within this class will have an enthalpy of fusion ( ⁇ H f ) as measured by differential scanning calorimetry of ⁇ 90 cal/g (measured by integrating heat flows recorded at temperatures > 80 °C while scanning at > 5 °C/min).
• T m or T g if not exhibiting a T m
• the backbone segments as taken together typically will have a T m less than or equal to 80 °C and a T g less than or equal to -10 °C.
• Elastomeric backbones will be particularly suitable, such will be typically comprised of ethylene and one or more of C 3 -C 12 ⁇ -olefins or diolefins, particularly propylene and 1-butene.
• copolymerizable monomers include geminally disubstituted olefins such as isobutylene, cyclic olefins such as cyclopentene, norbornene and alkyl-substituted norbornenes, and styrenic monomers such as styrene and alkyl substituted styrenes.
• Low crystallinity backbones are suitable, examples are high comonomer content ethylene copolymers (as described before), e.g., > than 8 mol% comonomer.
• the mass of the backbone will typically comprise at least 40 wt% of the total polymer mass, that of the backbone and the sidechains together, so the backbone typically will have a nominal weight-average molecular weight (M w ) weight of at least equal to or greater than about 50,000.
• M w weight-average molecular weight
• the term nominal is used to indicate that direct measurement of M w of the backbone is largely impossible but that characterization of the copolymer product will exhibit measurements of M w that correlate to a close approximate weight of the polymeric backbone inclusive only of the monoolefin mer derivatives and the insertion moieties of the sidebranches.
• the branched olefin copolymers comprising the above sidechains and backbones will typically have an M w equal to or greater than 50,000 as measured by GPC/DRI as defined for the examples.
• the M w typically can exceed 300,000, preferably 200,000, up to 500,000 or higher.
• thermoplastic elastomer composition of the invention can be prepared by a process comprising: A) copolymerizing ethylene or propylene, optionally with one or more copolymerizable monomers, in a polymerization reaction under conditions sufficient to form a copolymer having greater than 40% chain end- group unsaturation, a T m > 80 °C and a T g ⁇ 10 °C; B) copolymerizing the product of A) with ethylene and one or more copolymerizable monomers so as to prepare said branched olefin copolymer.
• the Tg is preferably less than -5°C, more preferably less than -10°C.
• the process step A) can be usefully practiced in a solution process in which ethylene and, optionally, one or more copolymerizable monomers, is contacted with a transition metal olefin polymerization catalyst activated by an alkylalumoxane cocatalyst, the mole ratio of aluminum to transition metal being less than about 220:1.
• the terminally unsaturated copolymer population so formed, with or without separation from copolymer product having only saturated ends, can then be copolymerized with ethylene and copolymerizable monomers in a separate reaction by solution, slurry or gas phase ethylene polymerization with an activated transition metal insertion polymerization catalyst, particularly a catalyst capable of incorporating the ethylene copolymers into said branched olefin copolymer.
• an activated transition metal insertion polymerization catalyst particularly a catalyst capable of incorporating the ethylene copolymers into said branched olefin copolymer.
• the process step A) can be practiced in a solution process in which propylene and, optionally, one or more copolymerizable monomers, is contacted with a stereorigid transition metal olefin polymerization catalyst, one capable of producing stereregular polypropylene, activated by any suitable cocatalyst, the reaction temperature kept at sufficiently high levels so as to achieve significant populations of terminally unsaturated polymer chains, e.g., greater than about 85 °C, preferably greater than about 90 °C.
• the terminally unsaturated copolymer population so formed, with or without separation from copolymer product having only saturated ends, can then be copolymerized with ethylene and copolymerizable monomers, or other selection of monomers suitable for the preparation of low crystallinity polymers, in a separate reaction by solution, slurry or gas phase ethylene polymerization with an activated transition metal insertion polymerization catalyst, particularly a catalyst capable of incorporating the propylene copolymers into said branched olefin copolymer having the low crystallinity backbone.
• an activated transition metal insertion polymerization catalyst particularly a catalyst capable of incorporating the propylene copolymers into said branched olefin copolymer having the low crystallinity backbone.
• Conditions sufficient to form the sidechain ethylene copolymer include using suitable ethylene and comonomer reactant ratios to assure the described sidechain olefin-derived unit constitution, plus catalyst and process conditions conducive to forming the unsaturated chain ends.
• the teachings of copending provisional application U.S. Ser. No. 60/037323 filed 02/07/97 are specific to suitable catalyst selection and use to prepare macromeric copolymer chains with a high yield of vinyl unsaturation.
• the metallocene catalyst used in the step A) preparation of the unsaturation-containing macromer can be essentially any catalyst capable of insertion polymerization of ethylene, it can be one capable of high comonomer incorporation capability (see below) or of low comonomer incorporation capability.
• polymeric vinyl-containing, ethylene- containing macromer product suitable as branches for a subsequent copolymerization reaction
• polymeric vinyl-containing, ethylene- containing macromer product can be prepared under solution polymerization conditions with preferred molar ratios of aluminum in the alkyl alumoxane activator, e.g., methyl alumoxane (MAO), to transition metal.
• MAO methyl alumoxane
• level is > 20 and ⁇ 175; more preferably > 20 and ⁇ 140; and, most preferably > 20 and ⁇ 100.
• the temperature, pressure and time of reaction depend upon the selected process but are generally within the normal ranges for a solution process. Thus temperatures can range from 20°C to 200°C, preferably from 30°C to 150°C, and more preferably from 50°C to 140°C.
• the pressures of the reaction generally can vary from atmospheric to 345 MPa, preferably to 182 MPa.
• temperatures will typically range from ambient to 190 °C with pressures from ambient to 3.45 MPa.
• the reactions can be run batchwise. Conditions for suitable slurry-type reactions are similar to solution conditions except reaction temperatures are limited to those below the melt temperature of the polymer.
• a supercritical fluid medium can be used with temperatures up to 250°C and pressures up to 345 MPa. Under high temperature and pressure reaction conditions, macromer product of lower molecular weight ranges are typically produced, e.g., M n about 1,500.
• polymeric vinyl-containing, propylene- containing macromer product suitable as branches for a subsequent copolymerization reaction
• metallocene catalysts suitable for preparing either of isotactic or syndiotactic polypropylene.
• a preferred reaction process for propylene macromers having high levels of terminal vinyl unsaturation is described in co- pending U.S. application 60/ 067,783, filed December 10, 1997, Attorney Docket
• the stereorigid transition metal catalyst compound is selected from the group consisting of bridged bis(indenyl) zirconocenes or hafnocenes.
• the transition metal catalyst compound is a dimethylsilyl-bridged bis(indenyl) zirconocene or hafnocene. More preferably, the transition metal catalyst compound is dimethylsilyl (2-methyl-4-phenylindenyl) zirconium or hafnium dichloride or dimethyl. In another preferred embodiment, the transition metal catalyst is a dimethylsilyl-bridged bis(indenyl) hafnocene such as dimethylsilyl bis(indenyl)hafnium dimethyl or dichloride.
• the method for preparing propylene- based macro ers having a high percentage of vinyl terminal bonds involves:
• the solution comprises a hydrocarbon solvent. More preferably, the hydrocarbon solvent is aromatic.
• the propylene monomers are preferably contacted at a temperature from 95°C to 115°C. More preferably, a temperature from 100°C to 110°C is used. Most preferably, the propylene monomers are contacted at a temperature from 105°C to 110°C.
• the pressures of the reaction generally can vary from atmospheric to 345 MPa, preferably to 182 MPa.
• the reactions can be run batchwise or continuously. Conditions for suitable slurry- type reactions will also be suitable and are similar to solution conditions, the polymerization typically being run in liquid propylene under pressures suitable to such. All documents are incorporated by reference for purposes of U.S. patent practice.
• branched olefin copolymer thermoplastic elastomer composition can be prepared directly from the selected olefins concurrently in the presence of a mixed catalyst system comprising at least one first transition metal olefin polymerization catalyst capable of preparing ethylene or propylene copolymers having greater than 40% chain end-group unsaturation and at least one second transition metal olefin polymerization catalyst capable of incorporating the ethylene or propylene homopolymer or copolymer sidechains into said branched olefin copolymer.
• a mixed catalyst system comprising at least one first transition metal olefin polymerization catalyst capable of preparing ethylene or propylene copolymers having greater than 40% chain end-group unsaturation and at least one second transition metal olefin polymerization catalyst capable of incorporating the ethylene or propylene homopolymer or copolymer sidechains into said branched olefin copolymer.
• This in situ method can be practiced by any method that permits both preparation of unsaturated macromers having crystalline, semi-crystalline or glassy properties and copolymerization of the macromers with comonomers constituting the low crystallinity backbone such that the branched copolymer is prepared.
• Gas phase, slurry and solution processes can be used under conditions of temperature and pressure known to be useful in such processes.
• Suitable first catalyst compounds that when activated can achieve high chain-end unsaturations specifically include those identified above with respect to the preparation of high vinyl or vinylidene-containing macromers.
• catalysts that are active for ethylene homopolymerization but do not incorporate higher carbon number monomers appreciably, as discussed above, or do so only with attendant decrease in M n will be particularly suitable for the crystalline or glassy sidechain preparation in the concurrent, or in situ, method of preparing the invention thermoplastic copolymer compositions of the invention, so long as the M n can be raised or maintained above the sidechain minimum.
• Suitable second catalyst compounds include those that are capable of good comonomer incorporation without significant depression in M n for the polymeric backbone under the temperature and pressure conditions used.
• transition metal catalyst compounds are typically used with activating co-catalyst components as described, e.g., alkyl alumoxanes and ionizing compounds capable of providing a stabilizing non-coordinating anion.
• co-catalyst components e.g., alkyl alumoxanes and ionizing compounds capable of providing a stabilizing non-coordinating anion.
• thermoplastic elastomer compositions according to the invention will have use in a variety of applications wherein other thermoplastic elastomer compositions have found use.
• Such uses include, but are not limited to, those known for the styrene block copolymers, e.g., styrene-isoprene-styrene and styrene-butadiene-styrene copolymers, and their hydrogenated analogs.
• Such include a variety of uses such as backbone polymers in adhesive compositions and molded articles. These applications will benefit from the increased use temperature range, typically exceeding the 80 - 90 °C limitation of the SBC copolymer compositions.
• compositions of the invention will also be suitable as compatibilizer compounds for polyolefin blends. Additionally, due to the inherent tensile strength, elasticity, and ease of melt processing, extruded film, coating and packaging compositions can be prepared comprising the invention thermoplastic elastomer compositions, optionally as modified with conventional additives and adjuvents. Further, in view of the preferred process of preparation using insertion polymerization of readily available olefins, the invention thermoplastic elastomer compositions can be prepared with low cost petrochemical feedstock under low energy input conditions (as compared to either of low temperature anionic polymerization or multistep melt processing conditions where vulcanization is needed to achieve discrete thermoplastic elastomer morphologies).
• Ethylene was added to the reactor as needed to maintain total system pressure at the reported levels (semi-batch operation). Ethylene flow rate was monitored using a Matheson mass flow meter (model number 8272-0424). To ensure the reaction medium was well- mixed, a flat-paddle stirrer rotating at 750 rpm was used.
• Reactor preparation The reactor was first cleaned by heating to 150°C in toluene to dissolve any polymer residues, then cooled and drained. Next, the reactor was heated using jacket water at 110°C and the reactor was purged with flowing nitrogen for a period of -30 minutes. Before reaction, the reactor was further purged using 10 nitrogen pressurize/vent cycles (to 100 psi) and 2 ethylene pressurize/vent cycles (to 300 psi). The cycling served three purposes: (1) to thoroughly penetrate all dead ends such as pressure gauges to purge fugitive contaminants, (2) to displace nitrogen in the system with ethylene, and (3) to pressure test the reactor.
• Catalyst preparation All catalyst preparations were performed in an inert atmosphere with ⁇ 1.5 ppm H 2 O content. In order to accurately measure small amounts of catalyst, often less than a milligram, freshly prepared catalyst stock solution/dilution methods were used in catalyst preparation. To maximize solubility of the metallocenes, toluene was used as a solvent. Stainless steel transfer tubes were washed with MAO to remove impurities, drained, and activator and catalyst were added by pipette, MAO first.
• Macromer synthesis First, the catalyst transfer tube was attached to a reactor port under a continuous flow of nitrogen to purge ambient air. Next, the reactor was purged and pressure tested as outlined above. Then, 600 ml of solvent was charged to the reactor and heated to the desired temperature. Comonomer (if any) was then added, temperature was allowed to equilibrate, and the base system pressure was recorded. The desired partial pressure of ethylene was added on top of the base system pressure. After allowing the ethylene to saturate the system (as indicated by zero ethylene flow), the catalyst was injected in a pulse using high pressure solvent. Reaction progression was monitored by reading ethylene uptake from the electronic mass flow meter.
• Cp 2 ZrCl 2 and (C 5 Me 4 SiMe 2 NC 12 H 23 )TiCl 2 catalysts were used in single-step, mixed metallocene syntheses where the macromers were prepared concurrently with the backbone and incorporated therein.
• Catalyst pairing For the mixed metallocene in situ example, the metallocene catalyst pair was selected such that both a good incorporating catalyst and a poorer incorporating catalyst was used. For this technology, the good incorporator will typically exhibit three times the incorporation capability of the poor incorporator or, even more preferably, five times the incorporation capability.
• Comonomer incorporation capability is defined and measured for each catalyst compound, for the purposes of the present invention, in terms of weight percent butene incorporation using a defined standard reaction condition as follows. A one liter autoclave reactor is purged 2 hours at 90°C with high purity nitrogen. The system is next purged of nitrogen using flowing ethylene. Next, 600 milliliters of toluene and 50 milliliters of liquid butene are added.
• the system is allowed to equilibrate at 90°C. Next, ethylene at 100 psig is added until the solution is saturated. A milligram of catalyst is added to 0.5 milliliters of 10 weight percent MAO in a stainless steel addition tube in an inert atmosphere glovebox. Depending on the reactivity of the catalyst, more or less catalyst/MAO solution may be required to assure substantial levels of polymerization without excessive reaction exotherms.
• the catalyst is injected into the reactor using pressurized solvent. Reactor pressure is maintained at 100 psig throughout reaction by adding ethylene as required. The reaction is terminated before the reactant compositions inside the reactor change substantially ( ⁇ 20% conversion, as determined by analysis of the reaction product). Comonomer incorporation is measured by 1H NMR and is reported as ethyl groups per 1000 carbon atoms.
• a stainless steel catalyst addition tube was prepared as outlined above. An aliquot of 1 milliliter of 10% methylalumoxane (MAO) solution in toluene was added, followed by 5 milliliters of a toluene solution containing 16 milligrams of (C 5 Me 4 SiMe 2 NC 12 H 23 )TiCl 2 . The sealed tube was removed from the glovebox and connected to a reactor port under a continuous flow of nitrogen. A flexible, stainless steel line from the reactor supply manifold was connected to the other end of the addition tube under a continuous flow of nitrogen.
• MAO methylalumoxane
• Macromer Synthesis The reactor was simultaneously purged of nitrogen and pressure tested using two ethylene fill/purge cycles (to 300 psig). Then, the reactor pressure was raised to -40 psi to maintain positive reactor pressure during setup operations. Jacket water temperature was set to 90°C and 600 milliliters of toluene and 10 milliliters of butene were added to the reactor. The stirrer was set to 750 rpm. Additional ethylene was added to maintain a positive reactor gauge pressure as gas phase ethylene was absorbed into solution. The reactor temperature controller was set to 90°C and the system was allowed to reach steady state. The ethylene pressure regulator was next set to 100 psig and ethylene was added to the system until a steady state was achieved as measured by zero ethylene uptake.
• the reactor was isolated and a pulse of toluene pressurized to 300 psig was used to force the catalyst solution from the addition tube into the reactor.
• the 100 psig ethylene supply manifold was immediately opened to the reactor in order to maintain a constant reactor pressure as ethylene was consumed by reaction.
• LCB Block Copolymer Synthesis A stainless steel catalyst addition tube was prepared as outlined above. An aliquot of 0.5 milliliter of 10% methylalumoxane (MAO) solution in toluene was added to the tube, followed by 1 milliliter of a toluene solution containing 0.5 milligrams of (C 5 Me SiMe 2 NC 12 H 23 )TiCl 2 per milliliter. The sealed tube was removed from the glovebox and connected to a reactor port under a continuous flow of nitrogen. A flexible, stainless steel line from the reactor supply manifold was connected to the other end of the addition tube under a continuous flow of nitrogen.
• MAO methylalumoxane
• the reactor temperature controller was set to 90°C. Next, 70 milliliters of butene were added to the macromer-containing reactor and the system was allowed to reach thermal equilibrium. Ethylene was next added to the system at 100 psig (total). After allowing the ethylene to saturate the system (as indicated by zero ethylene flow), the catalyst was injected in a pulse using high pressure solvent. Reaction progression was monitored by reading ethylene uptake from the electronic mass flow meter. Reaction was terminated by methanol injection after 15 minutes. The product was poured into an excess of isopropyl alcohol and evaporated to dryness. Total yield of LCB block copolymer was 42.6 grams.
• a stainless steel catalyst addition tube was prepared as outlined above. An aliquot of 0.5 milliliter of 10% methylalumoxane (MAO) solution in toluene was added, followed by 5 milliliters of a toluene solution containing 8 milligrams of Cp 2 ZrCl 2 . The sealed tube was removed from the glovebox and connected to a reactor port under a continuous flow of nitrogen. A flexible, stainless steel line from the reactor supply manifold was connected to the other end of the addition tube under a continuous flow of nitrogen.
• MAO methylalumoxane
• Macromer Synthesis The reactor was simultaneously purged of nitrogen and pressure tested using two ethylene fill/purge cycles (to 300 psig). Then, the reactor pressure was raised to -20 psi to maintain positive reactor pressure during setup operations. Jacket water temperature was set to 90°C and 600 milliliters of toluene and 2 milliliters of 80.6 weight percent norbornene in toluene were added to the reactor. The stirrer was set to 750 rpm. Additional ethylene was added to maintain a positive reactor gauge pressure as gas phase ethylene was absorbed into solution. The reactor temperature controller was set to 90°C and the system was allowed to reach steady state.
• the ethylene pressure regulator was next set to 30 psig and ethylene was added to the system until a steady state was achieved as measured by zero ethylene uptake.
• the reactor was isolated and a pulse of toluene pressurized to 300 psig was used to force the catalyst solution from the addition tube into the reactor.
• the 30 psig ethylene supply manifold was immediately opened to the reactor in order to maintain a constant reactor pressure as ethylene was consumed by reaction.
• LCB Block Copolymer Synthesis A stainless steel catalyst addition tube was prepared as outlined above. An aliquot of 0.5 milliliter of 10% methylalumoxane (MAO) solution in toluene was added, followed by 1 milliliter of a toluene solution containing 1 milligram of (C 5 Me 4 SiMe 2 NC 12 H 23 )TiCl 2 per milliliter. The sealed tube was removed from the glovebox and connected to a reactor port under a continuous flow of nitrogen. A flexible, stainless steel line from the reactor supply manifold was connected to the other end of the addition tube under a continuous flow of nitrogen.
• MAO methylalumoxane
• the reactor temperature controller was set to 60°C. Next, 60 milliliters of 80.6% norbornene in toluene were added and the system was allowed to reach thermal equilibrium. Ethylene was next added to the system at 100 psig (total).
• the catalyst was injected in a pulse using high pressure solvent. Reaction progression was monitored by reading ethylene uptake from the electronic mass flow meter. Reaction was terminated by methanol injection after 5 minutes. The product was poured into an excess of isopropyl alcohol and evaporated to dryness.
• a stainless steel catalyst addition tube was prepared as outlined above. An aliquot of 1 milliliter of 10% methylalumoxane (MAO) solution in toluene was added, followed by a toluene solution containing 0.25 milligrams of (C 5 Me 4 SiMe 2 NC 12 H 23 )TiCl 2 and 5 micrograms of Cp 2 ZrCl 2 . The sealed tube was removed from the glovebox and connected to a reactor port under a continuous flow of nitrogen. A flexible, stainless steel line from the reactor supply manifold was connected to the other end of the addition tube under a continuous flow of nitrogen.
• MAO methylalumoxane
• Tensile data were obtained at room temperature and 80°C according to method ASTM D-14 (in Figure 1, tensile strength at break at room temperature and 80°C is reported in units of pounds per square inch while elongation at break is reported as a percentage). Recovery was measured at room temperature using sample specimens identical to those used in ASTM D-14 test except the sample was stretched 150%, then released for 10 minutes and the percent recovery to the original dimensions measured directly using reference marks on the test sample.
• the ethylene/butene LCB block copolymers exhibit elastomeric properties superior to an EXACT 4033 (Exxon Chemical Company) ethylene/butene (E/B) random copolymer of similar density and equal or better to an ENGAGE 8100 (Dow Chemical Company) ethylene/octene (E/O) random copolymer of similar density (Table 2).
• EXACT 4033 Exxon Chemical Company
• E/B ethylene/butene random copolymer of similar density
• ENGAGE 8100 Low Chemical Company
• E/O ethylene/octene random copolymer of similar density
• LCB block copolymers melt at much higher temperatures than their linear counterparts, due to the crystallizable, low molecular weight branch component. It is interesting to note that the LCB block copolymers retain significant tensile strength even when heated above the melt temperature of their amorphous component (see 80°C tensile data). The observed high temperature strength may be due to multi-block-type networks in which amorphous material is anchored to high density, high melting zones by side chains.
• Product characterization The branched olefin copolymer product samples were analyzed by GPC using a Waters 150C high temperature system equipped with a DRI Detector, Shodex AT-806MS column and operating at a system temperature of 145°C.
• the solvent used was 1,2,4 trichlorobenzene, from which polymer sample solutions of 0.1 mg/ml concentration were prepared for injection.
• the total solvent flow rate was 1.0 ml/minute and the injection size was 300 microliters.
• GPC columns were calibrated using a series of narrow polystyrenes (obtained from Tosoh Corporation, Tokyo, 1989). For quality control, a broad- standard calibration based on the linear PE sample NBS-1475 was used.

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