Dinickel bisphenoxyiminato
complexes based on highly substituted p- and m-terphenyl backbones were synthesized,
and the corresponding atropisomers were isolated. In the presence
of a phosphine scavenger, Ni(COD)2, the phosphine-ligated syn-dinickel complexes copolymerized α-olefins and
ethylene in the presence of amines to afford 0.2–1.3% α-olefin
incorporation and copolymerized amino olefins and ethylene with a
similar range of incorporation (0.1–0.8%). The present rigid
catalysts provide a bimetallic strategy for insertion polymerization
of polar monomers without masking of the heteroatom group. The effects
of the catalyst structure on the reactivity were studied by comparisons
of the syn and anti atropisomers and the p- and m-terphenyl systems.
Polyester block polymers containing polylactide have garnered significant attention as renewable, degradable alternatives to traditional elastomers. However, the low glass transition of the PLA blocks limits the upper-use temperatures of the resulting elastomers. To improve the thermal performance, we explore a series of multiblock polyesters composed of poly(ε-decalactone) (PDL) and poly(cyclohexene phthalate) (PCHPE). These materials are prepared using switchable polymerization catalysis followed by chain extension. The strategy involves (i) alternating ring-opening copolymerization (ROCOP) of cyclohexene oxide and phthalic anhydride, (ii) εdecalactone ring-opening polymerization (ROP), and (iii) diisocyanate coupling of the telechelic triblocks to increase molar mass. The resulting multiblock polyesters are amorphous, and the blocks are phase separated; glass transition temperatures are ∼−45 and 100 °C. They show thermal resistance to mass loss with T d5% ∼ 285 °C and higher upper use temperatures compared to alternative aliphatic polyesters. The nanoscale phase behavior and correlated mechanical properties are highly sensitive to the block composition. The sample containing PCHPE = 26 wt % behaves as a thermoplastic elastomer with high elongation at break (ε b > 2450%), moderate tensile strength (σ b = 12 MPa), and low residual strain (ε r ∼ 4%). It shows elastomeric behavior from −20 to 100 °C and has a processing temperature range of ∼170 °C. At higher PCHPE content (59 wt %), the material has shape memory character with high strain fixation (250%) and recovery (96%) over multiple (25) recovery cycles. The multiblock polyesters are straightforward to prepare, and the methods presented here can be extended to produce a wide range of new materials using a other epoxides, anhydrides, and lactones. This first report on the thermal and mechanical properties highlights the significant potential for this class of polyesters as elastomers, rigid plastics, and shape memory materials.
Octahedral group 4 bisphenolate ether complexes, activated by methylaluminoxane, are highly active and stereospecific alpha-olefin polymerization catalysts. X-ray crystallographic analysis reveals the Zr and Hf complexes to be closely isostructural; the bond lengths of the Hf complex are slightly shorter, but the maximum deviation is only 0.062 A. Despite the structural similarity of the Hf and Zr complexes, the Hf complexes generate more highly stereoselective catalysts. In addition to the influence of the transition metal, the structure of the ligand has a large influence on the stereospecificity. Bis-tert-butyl phenyl substituted complexes of Hf and Zr, when activated by MAO at 50-80 degrees C, generate high molecular weight polypropylene (M(n) = 130,000-360,000 g/mol) with isotacticities [mmmm] > 97% and melting points as high as 165 degrees C.
Dinickel complexes supported by terphenyl ligands appended with phenoxy and imine donors were synthesized. Full substitution of the central arene blocks rotation around the aryl-aryl bond and allows for the isolation of atropisomers. The reported complexes perform ethylene polymerization in the presence of amines. The inhibiting effect of polar additives is up to 250 times lower on the syn isomer than the anti isomer. Comparisons with mononuclear systems indicate that the proximity of the metal centers leads to the observed inhibitory effect on the deactivation of the catalysts.
Binucleating
multidentate amine bis(phenolate) ligands with rigid terphenyl backbones
were designed to support two zirconium centers locked in close proximity.
Polymerizations of propylene or 1-hexene with the synthesized bimetallic
precatalysts resulted in polymers with significantly higher isotacticity
(up to 79% mmmm) in comparison to the stereoirregular
polymers produced with previously reported Cs-symmetric monometallic analogues. The bimetallic
precatalysts also display higher activity (up to 124 kg of poly(1-hexene)
(mmol of Zr)−1 h–1), in comparison
to the monometallic analogues, and among the highest activities reported
for nonmetallocene catalysts. The stereocontrol is consistent with
a bimetallic mechanism involving remote steric interactions with the
ligand sphere of the second metal center.
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