Huang Li-Shin, Tsai Chen-Yen, Chuang Hui-Ju, Ko Bao-Tsan
Department of Chemistry, National Chung Hsing University , Taichung 402, Taiwan.
Inorg Chem. 2017 Jun 5;56(11):6141-6151. doi: 10.1021/acs.inorgchem.7b00090. Epub 2017 May 16.
A series of structurally well-defined dinickel carboxylate complexes based on the BiIBTP derivatives [BiIBTP = bis(benzotriazole iminophenolate), where R = 3C for the propyl-bridged backbone and 5C for the 2,2-dimethyl-1,3-propyl-bridged backbone] were synthesized and developed for copolymerization of CO and epoxides. The one-pot reactions of nickel perchlorate with the BiIBTP-H proligands and an appropriate amount of carboxylic acid derivatives (CFCOOH or 4-X-CHCOH; X = H, CF, OMe) upon the addition of triethylamine in refluxing methanol (MeOH) afforded dinuclear nickel dicarboxylate complexes, which could be formulated as either [(BiIBTP)Ni(OCCF)] (1 and 2) or [(BiIBTP)Ni(OCCH-4-X)] (3-7). The dinickel monobenzoate complexes [(BiIBTP)Ni(OCPh)(ClO)(HO)] [R = 3C (8) and 5C (9)] were prepared by using a similar synthetic route in tetrahydrofuran under reflux with a ligand precursor to metal salt to benzoic acid ratio of 1:2:1 in the presence of NEt. Recrystallization of neutral nickel perchlorate complex 8 in a saturated MeOH or ethanol (EtOH) solution gave ionic and alcohol-solvated monobenzoate bimetallic analogues [(BiIBTP)Ni(OCPh)(S)]ClO, where S = MeOH (10) and EtOH (11). Single-crystal X-ray crystallography of dinickel analogues 1-11 indicates that the BiIBTP scaffold performs as a N,O,N,N,O,N-hexadentate ligand to chelate two Ni atoms, and the ancillary carboxylate group adopts a bridging bidentate bonding mode. Catalysis for copolymerization of carbon dioxide (CO) with cyclohexene oxide (CHO) by complexes 1-9 was systematically investigated, and the influence of carboxylate ligands on the catalytic behavior was also studied. Trifluoroacetate-ligated dinickel complex 1 efficiently catalyzed CO and CHO with a high turnover frequency (>430 h) in a controlled fashion, generating perfectly alternating poly(cyclohexenecarbonate) with large molecular weight (M > 50000 g/mol). In addition to CO/CHO copolymerization, bimetallic complex 1 was found to effectively copolymerize CO with 4-vinyl-1,2-cyclohexene oxide (VCHO) or cyclopentene oxide, producing the high carbonate contents of poly(VCHC-co-VCHO)s and highly alternating poly(cyclopentene carbonate)s, respectively. This study also enabled us to compare the catalytic efficiency of using cyclic epoxides with different ring strains or functional groups as comonomers by the dinickel catalyst 1.
基于BiIBTP衍生物[BiIBTP = 双(苯并三唑亚氨基苯酚盐),其中对于丙基桥连主链R = 3C,对于2,2 - 二甲基 - 1,3 - 丙基桥连主链R = 5C]合成并开发了一系列结构明确的二羧酸镍配合物,用于CO与环氧化物的共聚反应。在回流的甲醇(MeOH)中加入三乙胺后,高氯酸镍与BiIBTP - H前体配体和适量的羧酸衍生物(CFCOOH或4 - X - CH₂CO₂H;X = H、CF₃、OMe)的一锅法反应得到双核二羧酸镍配合物,其可被表述为[(BiIBTP)Ni(O₂CCF₃)] (1和2)或[(BiIBTP)Ni(O₂CCH₂ - 4 - X)] (3 - 7)。二镍单苯甲酸酯配合物[(BiIBTP)Ni(O₂CPh)(ClO₄)(H₂O)] [R = 3C (8)和5C (9)]是通过在四氢呋喃中回流,在NEt₃存在下,配体前体与金属盐与苯甲酸的比例为1:2:1的类似合成路线制备的。中性高氯酸镍配合物8在饱和MeOH或乙醇(EtOH)溶液中的重结晶得到离子型和醇溶剂化的单苯甲酸酯双金属类似物[(BiIBTP)Ni(O₂CPh)(S)]ClO₄,其中S = MeOH (10)和EtOH (11)。二镍类似物1 - 11的单晶X射线晶体学表明,BiIBTP支架作为一个N,O,N,N,O,N - 六齿配体螯合两个Ni原子,且辅助羧酸根基团采用桥连双齿键合模式。系统研究了配合物1 - 9对二氧化碳(CO₂)与环氧环己烷(CHO)共聚反应的催化作用,还研究了羧酸根配体对催化行为的影响。三氟乙酸酯配位的二镍配合物1以可控方式高效催化CO₂和CHO,具有高周转频率(>430 h⁻¹),生成具有高分子量(M > 50000 g/mol)的完美交替聚(环己烯碳酸酯)。除了CO/CHO共聚反应外,发现双金属配合物1能有效地使CO与4 - 乙烯基 - 1,2 - 环氧环己烷(VCHO)或环氧环戊烷共聚,分别生成高碳酸酯含量的聚(VCHC - co - VCHO)和高度交替的聚(环戊烯碳酸酯)。这项研究还使我们能够比较二镍催化剂1使用具有不同环应变或官能团的环状环氧化物作为共聚单体的催化效率。
