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Randomly Distributed Sulfur Atoms in the Main Chains of CO 2 ‐Based Polycarbonates: Enhanced Optical Properties
Author(s) -
Yue TianJun,
Ren BaiHao,
Zhang WenJian,
Lu XiaoBing,
Ren WeiMin,
Darensbourg Donald J.
Publication year - 2021
Publication title -
angewandte chemie
Language(s) - English
Resource type - Journals
eISSN - 1521-3757
pISSN - 0044-8249
DOI - 10.1002/ange.202012565
Subject(s) - polycarbonate , polymer , materials science , bimetallic strip , thermal stability , polymer chemistry , carbonate , propylene carbonate , catalysis , chemical engineering , organic chemistry , metal , chemistry , composite material , electrode , electrochemistry , metallurgy , engineering
Polymeric materials possessing both high refractive indices and high Abbe numbers are much in demand for the development of advanced optical devices. However, the synthesis of such functional materials is a challenge because of the trade‐off between these two properties. Herein, a synthetic strategy is presented for enhancing the optical properties of CO 2 ‐based polycarbonates by modifying the polymer's topological structure. Terpolymers with thiocarbonate and carbonate units randomly distributed in the polymers’ main chain were synthesized via the terpolymerization of cyclohexene oxide with a mixture of CO 2 and COS in the presence of metal catalysts, most notably a dinuclear aluminum complex. DFT calculations were employed to explain why different structural sequence were obtained with distinct bimetallic catalysts. Varying the CO 2 pressure made it possible to obtain terpolymers with tunable carbonate linkages in the polymer chain. More importantly, optical property studies revealed that terpolymers with comparable thiocarbonate and carbonate units exhibited a refractive index of 1.501 with an enhanced Abbe number as high as 48.6, much higher than the corresponding polycarbonates or polythiocarbonates. Additionally, all terpolymers containing varying thiocarbonate content displayed good thermal properties with T g >109 °C and T d >260 °C, suggesting little loss in the thermal stability compared to the polycarbonate. Hence, modification of the topological structure of the polycarbonate is an efficient method of obtaining polymeric materials with enhanced optical properties without compromising thermal performance.