Cyclic Polycarbonates by N-Heterocyclic Carbene-Mediated Ring-Expansion Polymerization and Their Selective Depolymerization to Monomers

Huang, Jin; Yan, Rui; Ni, Yongwei; Shi, Na; Li, Zhenjiang; Ma, Canliang; Guo, Kai

doi:10.1021/acssuschemeng.2c04230

Cited by 7 publications

(7 citation statements)

References 102 publications

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“…The initiation of the copolymerization involves the nucleophilic attack on the carbonyl carbon of the comonomers (VL or 3EG) by iPr-NHC, yielding a tetrahedral intermediate (Int1 VL or Int1 3EG ; Figure S10). 51,67 The calculation revealed that the nucleophilic addition to VL required relatively higher activation energy compared with that to 3EG (iPr-NHC/3EG; ΔG ‡ = 16.52 vs 9.60 kcal mol −1 ), while Int1 VL was thermodynamically favored over Int1 3EG (−10.17 vs −9.62 kcal mol −1 ), indicating that Int1 generated from the interaction between NHC and comonomers was the thermodynamically controlled product. The copolymerization of 3EG exhibited slow kinetics, and the propagation in the ZROP of 3EG was previously reported to be the rate-determining step; 50 4).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…The short average block lengths of the copolymer could stem from a chain transfer reaction induced by the high catalytic activity of Me-NHC . We previously reported that bulky substituents of NHC, e.g., diisopropyl NHC ( i Pr-NHC ), resulted in low catalytic activity because the interaction between the NHC and MC was sterically hindered . Therefore, to mitigate the chain transfer reaction and subsequently obtain a cyclic block copolymer, i Pr-NHC was employed for ZcROP.…”

Section: Resultsmentioning

confidence: 99%

“…Based on our previous work, which demonstrated that dimethyl NHC ( Me-NHC ) enabled fast ZROP of macrocyclic carbonate (MC), the copolymerization of VL and 3EG was performed in a [NHC] 0 :[VL] 0 :[3EG] 0 ratio of 1:20:20 with [VL] 0 = 1 M in 0.5 mL dichloromethane (DCM) at ambient temperature. After 1 h, a 1 H NMR spectroscopy analysis revealed the formation of poly(VL- co -3EG) with relatively short blocks of VL ( L VL = 1.7) and 3EG ( L 3EG = 2.2) and the absence of a hydroxyl chain end (Table S1, entry 1).…”

Section: Resultsmentioning

confidence: 99%

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One-Pot, One-Step to Access Cyclic Amphiphilic Block Copoly(carbonate-b-ester)

Shi,

Lu,

Guo

et al. 2023

ACS Appl. Polym. Mater.

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Amphiphilic block copolymers containing a cyclic topology exhibit distinct physical properties that can be exploited to obtain fascinating nanostructures for various applications. So far, these copolymers have been generally prepared via multistep approaches. Herein, we report the simultaneous zwitterionic copolymerization of δ-valerolactone (VL) and triethylene glycol carbonate (3EG) mediated by N-heterocyclic carbene to yield a cyclic amphiphilic block copoly(ester-b-carbonate) in a one-pot, one-step strategy. The copolymerization temperature has a considerable impact on the block length (L VL and L 3EG); thus, a block copolymer (L VL = 12.7 and L 3EG = 10.1) is obtained at a low temperature (−25 °C), whereas a random copolymer is obtained at 50 °C with a high overall conversion (≥95%). The copolymerization proceeds with a 150 times faster consumption of VL compared to that of 3EG with reactivity ratios (r) r VL ≫ r 3EG (r VL ≈ 5, r 3EG ≈ 0.055), determined using the error-in-variables-model method, demonstrating the VL block chain during copolymerization. Moreover, a theoretical study indicates that the obtained copolymer is not a kinetically controlled product but rather a thermodynamically controlled product. Scanning and transmission electron microscopies revealed that the copoly(ester-b-carbonate) self-assembled in a tetrahydrofuran/water solvent mixture (V THF/V H2O = 1:5) to form a cubic nanostructure.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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One-Pot, One-Step to Access Cyclic Amphiphilic Block Copoly(carbonate-b-ester)

Shi,

Lu,

Guo

et al. 2023

ACS Appl. Polym. Mater.

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“…The ring structures of attained MCs were associated with little to no ring strains, thus leading to entropy-driven ROP of MCs. 27,28 We hypothesize that the thermodynamics of ROP might be altered to be enthalpy-driven through constraining MCs by the supramolecular interaction with auxiliary, thus increasing the ring strain and ΔH p . To this end, inspired by the electrostatic interaction between the crown ether and an alkali cation (M + ) 29−31 yielding a supramolecular complex to alter the ring strain of crown ether, 32,33 imitate crown ether was designed, aiming to verify our hypothesis that the thermodynamics of ROP of 4EGMC can be modulated by an auxiliary.…”

Section: ■ Introductionmentioning

confidence: 99%

Understanding Alkali Cation-Assisted Ring-Opening Polymerization of Macrocyclic Carbonate: Kinetics and Thermodynamics

Qu,

Hu,

Guo

et al. 2023

Macromolecules

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Control over polymerization thermodynamics and kinetics enables the generation of polymers with on-demand properties. This is exemplified by the ring-opening polymerization of tetraethylene glycol carbonate (4EGMC) using an alkali cation (M + )-based binary catalytic system at ambient temperature. By introducing a guanidine catalyst [(1,5,7-triazabicyclo[4.4.0]dec-5-ene), TBD], the alkali cationassisted ring-opening polymerization of macrocyclic carbonate was ca. 120−270 times faster than the reaction without an alkali cation, M + (0.16−0.36 min −1 with M + vs 0.001 min −1 without M + ). Moreover, the interaction between 4EGMC and M + led to an increase in the ring strain, supported by both bench experiments and computational simulations. This interaction altered the driving force of polymerization from the change of entropy to enthalpy, which revealed the pivotal role of alkali cations in regulating the ring-opening polymerization of macrocyclic carbonate.

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“…Ample methods exist that join polymer chain ends together in processes collectively coined post-polymerization modifications. [1][2][3][4] These coupling reactions remain attractive because they offer the possibility of transforming linear, often easily accessible, polymer chains into new shapes, such as cycles [5][6][7][8] and star polymers, [9][10][11] or new, predetermined sizes in the case of dimerization. [12][13][14][15] In general, synthetic methods rely on modification of the polymer chain ends to useful functional groups that are amenable to participation in "click" reactions, 3,13,[16][17][18][19][20] Diels-Alder cycloadditions, [21][22][23] and esterification reactions, [24][25][26] as examples.…”

Section: Introductionmentioning

confidence: 99%

Room temperature nickel‐catalyzed reductive coupling of end‐brominated polystyrene chains

Chong,

Burch,

Otero

et al. 2023

Journal of Polymer Science

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Facile, room‐temperature coupling of brominated polymer chains can be accomplished in high yields (~80%) using a nickel‐based catalytic cycle that also includes magnesium and zinc. The extent of coupling (Xc) was found to be similarly high when performed under vacuum or with a nitrogen purge, although its effectiveness varied significantly as a function of the solvent, reagents, and the structure of the polymer chain end. Kinetic studies show that even at room temperature, nearly all coupling occurs within the first ~2 h of the reaction when performed under nitrogen or vacuum, with accompanying color changes occurring in the catalytic system coinciding with catalytic activity. One step of the mechanistic cycle is proposed to occur via chain‐end radical intermediates inserted into the catalytic cycle, consistent with the addition of a radical trap essentially thwarting the dimerization by capturing the polymer radical and preventing its inclusion in the reaction. The presence of aryl bromide functional groups, however, does not impede the coupling reaction, demonstrating the catalyst's preference for the chain‐end alkyl bromides under our conditions. The impact and necessity of the other components were also explored, supporting the importance of the MgCl2 serving as a Lewis acid to promote the reactivity of the CBr end groups.

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Cyclic Polycarbonates by N-Heterocyclic Carbene-Mediated Ring-Expansion Polymerization and Their Selective Depolymerization to Monomers

Cited by 7 publications

References 102 publications

One-Pot, One-Step to Access Cyclic Amphiphilic Block Copoly(carbonate-b-ester)

One-Pot, One-Step to Access Cyclic Amphiphilic Block Copoly(carbonate-b-ester)

Understanding Alkali Cation-Assisted Ring-Opening Polymerization of Macrocyclic Carbonate: Kinetics and Thermodynamics

Room temperature nickel‐catalyzed reductive coupling of end‐brominated polystyrene chains

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