Organoboron-mediated polymerizations

Zhang, Yao-Yao; Yang, Guan-Wen; Lu, Chenjie; Zhu, Xiao-Feng; Wang, Yuhui; Wu, Guang-Peng

doi:10.1039/d3cs00115f

“…Organocatalysis has been demonstrated as the efficient synthetic protocol for metal-free biodegradable polyesters. , Since the initial discovery, various kinds of organic molecules have been screened to perform ROP with different proposed mechanisms. , By transferring organocatalysis from the batch reactor into the microreactor, remarkable advantages are achieved toward biodegradable polymer synthesis. The first example of continuous flow organocatalyzed ring-opening polymerizations to biodegradable polyesters was reported by Wennekes et al and Guo et al, respectively, in 2016.…”

Section: Continuous Flow Organocatalysis To Biodegradable Polymersmentioning

confidence: 99%

Microreactor-Based Green Synthetic Platform for Flow Synthesis of Biodegradable Polymers

Hu,

Feng,

Hu

et al. 2024

Ind. Eng. Chem. Res.

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Green synthetic strategies to biodegradable polymers have been paid much attention in the background of global attention to sustainable development. Bio- and organocatalyses for ring-opening polymerizations of cyclic monomers offer metal-free biodegradable polymers under mild conditions. With the benefits of a huge surface-to-volume ratio and flow characteristic, a microreactor exhibits unique advantages that cannot be had in a traditional batch reactor. The combination of flow chemistry and bio/organocatalysis provides a green synthetic platform for fast, efficient, and scalable generation of biodegradable polyesters and polycarbonates. This review summarizes ring-opening polymerizations of lactones, lactides, and carbonates by continuous flow biocatalysis, organocatalysis, and biochemical catalysis. Accelerated apparent polymerization rates, improved control of molecular weights and polydispersities, higher end group fidelities, and novel degradable polymeric materials with tunable properties were achieved by using a microreactor-based green synthetic platform. The challenges and opportunities are proposed with the aim to advance the development of the green synthesis and application of sustainable polymers.

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“…Since Shea's seminal discovery, considerable attention has been dedicated to this research topic. [2][3][4][5][6][7][8][9][10][11][12] Various polymer architectures were synthesized by combining polyhomologation with other living and controlled/living polymerization techniques, including anionic polymerization, [13][14][15] atom transfer radical polymerization (ATRP), [16] reversible addition-fragmentation chain transfer polymerization (RAFT), [17] and ring-opening metathesis polymerization (ROMP). [18,19] Sulfoxonium methylide monomer was replaced with allylic arsonium ylide monomers by Mioskowski and coworkers in 2003.…”

Section: Introductionmentioning

confidence: 99%

Boron‐Catalyzed C1 Copolymerization of Arsonium and Sulfoxonium Ylides toward Unrepresented Structures and Fluorescence Properties

Zhou,

Hadjichristidis

2024

Angew Chem Int Ed

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The first synthesis of well‐defined poly(methylene‐co‐1,1‐diphenylpropenenylene) (C1‐co‐C1’), equivalent to poly(ethylene‐co‐diphenylbutadiene) copolymer was accomplished by C1 copolymerization of novel diphenylpropenyl triphenyl arsonium ylides (Ph2AY) and dimethylsulfoxonium methylide (Me2SY) using B‐thexylborepane as an initiator. All polymerization conditions, including feed ratio, temperature, and reaction time, were optimized. A series of photoluminescent poly(ethylene‐co‐diphenylbutadiene) were synthesized at different feed ratios, opening a new synthetic horizon for poly(ethylene‐co‐disubstitutedbutadiene). Notably, a new C1 segment, resulting from a double bond rearrangement, was confirmed by NMR, resulting in an unprecedented two‐monomer three‐structure random terpolymer. An unexpected red‐shift phenomenon in the fluorescence spectra was observed with an increase in the ratio of Ph2AY in the copolymer. This shift is attributed to the aggregation of diphenylbutadiene segment, akin to through‐space conjugation (TSC), likely induced by a decrease in the crystallinity of copolymers. Furthermore, another disubstituted allylic triphenyl arsonium ylides, (E)‐2‐phenylbutenyl triphenyl arsonium ylide (MePhAY) was also synthesized and investigated. These additional compounds expand knowledge and potential applications of such copolymerization techniques in advanced materials.

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Boron‐Catalyzed C1 Copolymerization of Arsonium and Sulfoxonium Ylides toward Unrepresented Structures and Fluorescence Properties

Zhou,

Hadjichristidis

2024

Angewandte Chemie

0

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The first synthesis of well‐defined poly(methylene‐co‐1,1‐diphenylpropenenylene) (C1‐co‐C1’), equivalent to poly(ethylene‐co‐diphenylbutadiene) copolymer was accomplished by C1 copolymerization of novel diphenylpropenyl triphenyl arsonium ylides (Ph2AY) and dimethylsulfoxonium methylide (Me2SY) using B‐thexylborepane as an initiator. All polymerization conditions, including feed ratio, temperature, and reaction time, were optimized. A series of photoluminescent poly(ethylene‐co‐diphenylbutadiene) were synthesized at different feed ratios, opening a new synthetic horizon for poly(ethylene‐co‐disubstitutedbutadiene). Notably, a new C1 segment, resulting from a double bond rearrangement, was confirmed by NMR, resulting in an unprecedented two‐monomer three‐structure random terpolymer. An unexpected red‐shift phenomenon in the fluorescence spectra was observed with an increase in the ratio of Ph2AY in the copolymer. This shift is attributed to the aggregation of diphenylbutadiene segment, akin to through‐space conjugation (TSC), likely induced by a decrease in the crystallinity of copolymers. Furthermore, another disubstituted allylic triphenyl arsonium ylides, (E)‐2‐phenylbutenyl triphenyl arsonium ylide (MePhAY) was also synthesized and investigated. These additional compounds expand knowledge and potential applications of such copolymerization techniques in advanced materials.

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Organoboron-mediated polymerizations

Abstract: This review provides a comprehensive summary of organoboron-mediated free radical polymerization, Lewis pair polymerization, ionic polymerization, and polyhomologation, laying the groundwork for further establishment of polymerization methods.

Cited by 6 publications

References 309 publications

Microreactor-Based Green Synthetic Platform for Flow Synthesis of Biodegradable Polymers

Microreactor-Based Green Synthetic Platform for Flow Synthesis of Biodegradable Polymers

Boron‐Catalyzed C1 Copolymerization of Arsonium and Sulfoxonium Ylides toward Unrepresented Structures and Fluorescence Properties

Boron‐Catalyzed C1 Copolymerization of Arsonium and Sulfoxonium Ylides toward Unrepresented Structures and Fluorescence Properties

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