Strategies for Achieving Oxygen Tolerance in Reversible Addition-Fragmentation Chain Transfer Polymerization

被引:22
作者
Ng, Gervase [1 ,2 ]
Prescott, Stuart W. W. [1 ,2 ]
Postma, Almar [3 ]
Moad, Graeme [3 ]
Hawker, Craig J. J. [4 ,5 ,6 ]
Boyer, Cyrille [1 ,2 ]
机构
[1] Univ New South Wales, Ctr Adv Macromol Design, Sydney, NSW 2052, Australia
[2] Univ New South Wales, Australian Ctr Nanomed, Sch Chem Engn, Sydney, NSW 2052, Australia
[3] CSIRO Mfg, Bag 10, Clayton, Vic 3169, Australia
[4] Univ Calif Santa Barbara, Mat Res Lab, Santa Barbara, CA 93106 USA
[5] Univ Calif Santa Barbara, Dept Mat Chem, Santa Barbara, CA 93106 USA
[6] Univ Calif Santa Barbara, Dept Biochem, Santa Barbara, CA 93106 USA
来源
MACROMOLECULAR CHEMISTRY AND PHYSICS | 2023年 / 224卷 / 19期
基金
澳大利亚研究理事会;
关键词
controlled; living radical polymerization; oxygen tolerance; RAFT polymerization; LIVING RADICAL POLYMERIZATION; PET-RAFT POLYMERIZATION; ROOM-TEMPERATURE RAFT; MULTIBLOCK COPOLYMERS; DIFFUSION-COEFFICIENTS; COMBINATORIAL APPROACH; ORGANIC-SOLVENTS; GLUCOSE-OXIDASE; SURFACE; MECHANISM;
D O I
10.1002/macp.202300132
中图分类号
O63 [高分子化学(高聚物)];
学科分类号
070305 ; 080501 ; 081704 ;
摘要
Reversible addition-fragmentation chain transfer polymerization (RAFT) is a popular method for the synthesis of well-defined macromolecules, but its sensitivity to oxygen is a major limitation for many industrial applications. Recent research has focused on developing strategies to confer oxygen tolerance onto RAFT polymerization, eliminating the need for deoxygenation steps and allowing for simpler reaction conditions. This minireview highlights several promising approaches to achieve oxygen tolerance in RAFT polymerization, including enzyme-mediated, alkylborane-initiated, and photomediated methods. The potential applications of oxygen-tolerant RAFT polymerization are also discussed, demonstrating the promise for significant advances in large-scale industrial polymer synthesis.
引用
收藏
页数:23
相关论文
共 164 条
[11]   Glucose oxidase - An overview [J].
Bankar, Sandip B. ;
Bule, Mahesh V. ;
Singhal, Rekha S. ;
Ananthanarayan, Laxmi .
BIOTECHNOLOGY ADVANCES, 2009, 27 (04) :489-501
[12]   Polymer Brushes via Surface-Initiated Controlled Radical Polymerization: Synthesis, Characterization, Properties, and Applications [J].
Barbey, Raphael ;
Lavanant, Laurent ;
Paripovic, Dusko ;
Schuewer, Nicolas ;
Sugnaux, Caroline ;
Tugulu, Stefano ;
Klok, Harm-Anton .
CHEMICAL REVIEWS, 2009, 109 (11) :5437-5527
[13]   THE SOLUBILITY OF OXYGEN AND OZONE IN LIQUIDS [J].
BATTINO, R ;
RETTICH, TR ;
TOMINAGA, T .
JOURNAL OF PHYSICAL AND CHEMICAL REFERENCE DATA, 1983, 12 (02) :163-178
[14]   THE MECHANISM AND KINETICS OF THE INITIATION OF POLYMERISATION BY SYSTEMS CONTAINING HYDROGEN PEROXIDE [J].
BAXENDALE, JH ;
EVANS, MG ;
PARK, GS .
TRANSACTIONS OF THE FARADAY SOCIETY, 1946, 42 (3-4) :155-169
[15]   Glucose Oxidase-Mediated Polymerization as a Platform for Dual-Mode Signal Amplification and Biodetection [J].
Berron, Brad J. ;
Johnson, Leah M. ;
Ba, Xiao ;
McCall, Joshua D. ;
Alvey, Nicholas J. ;
Anseth, Kristi S. ;
Bowman, Christopher N. .
BIOTECHNOLOGY AND BIOENGINEERING, 2011, 108 (07) :1521-1528
[16]   ROLE OF OXYGEN IN POLYMERIZATION REACTIONS [J].
BHANU, VA ;
KISHORE, K .
CHEMICAL REVIEWS, 1991, 91 (02) :99-117
[17]   Interaction of surfactant and initiator types in emulsion polymerisations: A comparison of ammonium persulfate and hydrogen peroxide [J].
Boutti, S ;
Zafra, RD ;
Graillat, C ;
McKenna, TF .
MACROMOLECULAR CHEMISTRY AND PHYSICS, 2005, 206 (14) :1355-1372
[18]   INHIBITION AND RETARDATION OF VINYL POLYMERIZATION [J].
BOVEY, FA ;
KOLTHOFF, IM .
CHEMICAL REVIEWS, 1948, 42 (03) :491-525
[19]   Origins and Development of Initiation of Free Radical Polymerization Processes [J].
Braun, Dietrich .
INTERNATIONAL JOURNAL OF POLYMER SCIENCE, 2009, 2009
[20]   INITIATION RATES FOR AUTOXIDATION OF TRIALKYLBORANES - EFFECT OF A STERIC FACTOR ON INITIATION RATE [J].
BROWN, HC ;
MIDLAND, MM .
JOURNAL OF THE CHEMICAL SOCIETY D-CHEMICAL COMMUNICATIONS, 1971, (13) :699-&
12345678910