Recent advances in alternating copolymers: The synthesis, modification, and applications of precision polymers

Huang, Jing; Turner, S. Richard

doi:10.1016/j.polymer.2017.01.020

Cited by 109 publications

(68 citation statements)

References 177 publications

(248 reference statements)

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“…Figure 6B shows the 1 HNMR spectrum of the product after the treatment with n-BuNH 2 and corresponding random copolymer.T he spectrum is quite similar to that of the 1:1r andom copolymer, and an analysis of the peak integration ratios indicated a1 :1 ratio of the two units. Furthermore,F igure 5C shows the 13 CNMR spectrum of the obtained copolymer in comparison with the random copolymer, and the spectra exhibit almost identical shapes and peaksplitting patterns.P eculiar peaks specifically due to the alternating sequence were not observed, though 13 CNMR spectroscopy of the alternating copolymer was different from random ones,and it clarified the sequence in previous works of sequence control. [23,24,26,33] On the other hand, we recorded quite different MALDI-TOFm ass spectra [34] from the product after cleavage with nbutylamine to the random copolymer ( Figure 5D).…”

Section: Resultsmentioning

confidence: 50%

“…An alternating copolymer (left) that consists only of one type of repeatingunit (acryl amide) with different substituents in comparison with the corresponding random copolymer (right). al arge difference in electron density between the two monomers, [13][14][15][16][17][18][19] or by addition of aL ewis acid to an electron-poor comonomer in order to further deplete electron density. [20,21] It is thus easy to understand that achieving genuine sequence control in the copolymerization of one type of monomer with different pendants is very challenging.…”

Section: Introductionmentioning

confidence: 99%

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Unprecedented Sequence Control and Sequence‐Driven Properties in a Series of AB‐Alternating Copolymers Consisting Solely of Acrylamide Units

et al. 2020

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Herein, we report a method to synthesize a series of alternating copolymers that consist exclusively of acrylamide units. Crucial to realizing this polymer synthesis is the design of a divinyl monomer that contains acrylate and acrylamide moieties connected by two activated ester bonds. This design, which is based on the reactivity ratio of the embedded vinyl groups, allows a “selective” cyclopolymerization, wherein the intramolecular and intermolecular propagation are repeated alternately under dilute conditions. The addition of an amine to the resulting cyclopolymers afforded two different acryl amide units, i.e., an amine‐substituted acryl amide and a 2‐hydroxy‐ethyl‐substituted acryl amide in alternating sequence. Using this method, we could furnish ten types of alternating copolymers; some of these exhibit unique properties in solution and in the bulk, which are different from those of the corresponding random copolymers, and we attributed the differences to the alternating sequence.

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Section: Resultsmentioning

confidence: 50%

Section: Introductionmentioning

confidence: 99%

Unprecedented Sequence Control and Sequence‐Driven Properties in a Series of AB‐Alternating Copolymers Consisting Solely of Acrylamide Units

et al. 2020

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“…It is well known that electron‐deficient maleic anhydride and maleimide monomers can readily form alternating copolymers with electron‐rich monomers such as styrene, α‐methyl styrene, stilbene, vinyl acetate, etc . Of particular interest in our group are the stilbene‐maleic anhydride/maleimide alternating copolymers . First prepared by Wagner‐Jauregg in 1930, the stilbene‐maleic anhydride copolymer was regarded to be the earliest reported synthetic copolymer in literature .…”

Section: Introductionmentioning

confidence: 99%

Enhanced Fluorescence Properties of Stilbene‐Containing Alternating Copolymers

Huang

Geng

Peng

et al. 2017

Macromol. Rapid Commun.

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In recent years, nonconjugated, fluorophore-free organic polymers have emerged as potentially useful light-emitting materials. The fluorescence properties of a novel class of nonconjugated, tert-butyl carboxylate functionalized stilbene-containing alternating copolymers are investigated in this work. These sterically crowded, semi-rigid copolymers exhibit very strong blue fluorescence in organic solvents upon irradiation. The origin of the fluorescent band with high quantum yield is attributed to the "through space" π-π interactions between the phenyl rings from the stilbene and CO groups from the anhydride groups. To the best of our knowledge, the di-tert-butyl group-containing stilbene and maleic anhydride alternating copolymer showed one of the highest fluorescent intensities among all fluorophore-free polymers. The excellent linearity of the luminescence property of this copolymer is an important attribute for future potential quantitative applications. The fluorescence is maintained when the tert-butyl groups are removed and the resulting carboxylic acid-functionalized copolymer is dissolved in water at neutral pH, which can render these copolymers as attractive candidates for diagnostic and therapeutic applications.

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“…Electron‐accepting maleic anhydride (MAn) and N ‐substituted maleimides (RMIs) readily provide alternating copolymers by radical copolymerization with electron‐donating olefins, such as styrenes, vinyl ethers, isobutene, and other several olefins . The produced MAn copolymers are used as functional polymers, such as paints, industrial resins, sizing agents for paper, surface active agents, additives for food, anticancer drugs, and so on .…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Ozone Degradation of Alternating Copolymers ofN‐Substituted Maleimides with Diene Monomers

Nomura

Tsujii

Matsumoto

2017

Macro Chemistry & Physics

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Radical copolymerization of N‐substituted maleimides (RMIs) and maleic anhydride (MAn) in combination with 2,4‐dimethyl‐1,3‐pentadiene (DMPD) and 1,3‐pentadiene (PD) provides alternating copolymers with excellent thermal stability. Onset temperatures of decomposition are 280–331 and 336–371 °C for the copolymers with DMPD and PD, respectively. Glass transition temperatures of RMI copolymers are in a wide range of 54–138 °C depending on the bulkiness of N‐substituents. MAn copolymers are transformed to the corresponding RMI copolymers by postpolymerization reactions, which consist of quantitative addition of an alkylamine to an anhydride moiety of MAn copolymers and the subsequent heating. The copolymers synthesized in this study include ozone‐degradable carbon‐to‐carbon double bonds in their main chain. Molecular weight of the copolymers rapidly decreases by ozone degradation. Surface modification of casted polymer films is also performed by exposure to ozone‐containing air.

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Recent advances in alternating copolymers: The synthesis, modification, and applications of precision polymers

Cited by 109 publications

References 177 publications

Unprecedented Sequence Control and Sequence‐Driven Properties in a Series of AB‐Alternating Copolymers Consisting Solely of Acrylamide Units

Unprecedented Sequence Control and Sequence‐Driven Properties in a Series of AB‐Alternating Copolymers Consisting Solely of Acrylamide Units

Enhanced Fluorescence Properties of Stilbene‐Containing Alternating Copolymers

Synthesis and Ozone Degradation of Alternating Copolymers ofN‐Substituted Maleimides with Diene Monomers

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