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探索羟基和磷酸酯封端的-1,4-聚异戊二烯链在天然橡胶物理交联点形成中的作用:来自分子动力学模拟的见解。

Exploring the Role of Hydroxy- and Phosphate-Terminated -1,4-Polyisoprene Chains in the Formation of Physical Junction Points in Natural Rubber: Insights from Molecular Dynamics Simulations.

作者信息

Dixit Mayank, Taniguchi Takashi

机构信息

Graduate School of Engineering, Kyoto University, Nishikyo-ku, Kyoto 615-8510, Japan.

出版信息

ACS Polym Au. 2024 May 15;4(4):273-288. doi: 10.1021/acspolymersau.4c00019. eCollection 2024 Aug 14.

DOI:10.1021/acspolymersau.4c00019
PMID:39156555
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11328332/
Abstract

This study elucidates the pivotal role of terminal structures in -1,4-polyisoprene (PI) chains, contributing to the exceptional mechanical properties of Hevea natural rubber (NR). NR's unique networking structure, crucial for crack resistance, elasticity, and strain-induced crystallization, involves two terminal groups, ω and α. The proposed ω terminal structure is dimethyl allyl-(-1,4-isoprene), and α terminals exist in various forms, including hydroxy, ester, and phosphate groups. Among others, we investigated three types of -1,4-PI with different terminal combinations: PI (pure PI with H terminal), PI (PI with ω and α6 terminals), and PI (PI with ω and PO terminals) and revealed significant dynamics variations. Hydrogen bonds between α6 and α6 and PO and PO residues in PI and PI systems induce slower dynamics of hydroxy- and phosphate-terminated PI chains. Associations between α6 and α6 and PO and PO terminals are markedly stronger than ω and ω, and hydrogen terminals in PI and PI systems. Phosphate terminals exhibit a stronger mutual association than hydroxy terminals. Potentials of mean force analysis and cluster-formation-fraction computations reveal stable clusters in PI and PI , supporting the formation of polar aggregates (physical junction points). Notably, phosphate terminal groups facilitate large and highly stable phosphate polar aggregates, crucial for the natural networking structure responsible for NR's outstanding mechanical properties compared to synthetic PI rubber. This comprehensive investigation provides valuable insights into the role of terminal groups in -1,4-PI melt systems and their profound impact on the mechanical properties of NR.

摘要

本研究阐明了端基在-1,4-聚异戊二烯(PI)链中的关键作用,这有助于三叶橡胶天然橡胶(NR)具有优异的机械性能。NR独特的网络结构对于抗裂性、弹性和应变诱导结晶至关重要,它涉及两个端基,即ω端基和α端基。所提出的ω端基结构是二甲基烯丙基-(-1,4-异戊二烯),α端基以多种形式存在,包括羟基、酯基和磷酸酯基。其中,我们研究了三种具有不同端基组合的-1,4-PI:PI(具有H端基的纯PI)、PI(具有ω和α6端基的PI)和PI(具有ω和PO端基的PI),并揭示了显著的动力学变化。PI和PI体系中α6与α6以及PO与PO残基之间的氢键导致羟基封端和磷酸酯封端的PI链动力学较慢。α6与α6以及PO与PO端基之间的缔合明显强于PI和PI体系中的ω与ω以及氢端基。磷酸酯端基之间的相互缔合比羟基端基更强。平均力势分析和簇形成分数计算揭示了PI和PI中的稳定簇,支持了极性聚集体(物理交联点)的形成。值得注意的是,磷酸酯端基有助于形成大的且高度稳定的磷酸酯极性聚集体,这对于天然网络结构至关重要,与合成PI橡胶相比,该结构赋予了NR出色的机械性能。这项全面的研究为端基在-1,4-PI熔体体系中的作用及其对NR机械性能的深远影响提供了有价值的见解。

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本文引用的文献

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J Phys Chem B. 2024 Mar 7;128(9):2168-2180. doi: 10.1021/acs.jpcb.3c06876. Epub 2024 Feb 28.
2
Role of Terminal Groups of -1,4-Polyisoprene Chains in the Formation of Physical Junction Points in Natural Rubber.-1,4-聚异戊二烯链末端基团在天然橡胶物理交联点形成中的作用。
Biomacromolecules. 2023 Aug 14;24(8):3589-3602. doi: 10.1021/acs.biomac.3c00355. Epub 2023 Aug 1.
3
Influence of Non-Rubber Components on the Properties of Unvulcanized Natural Rubber from Different Clones.
非橡胶成分对不同克隆未硫化天然橡胶性能的影响。
Polymers (Basel). 2022 Apr 26;14(9):1759. doi: 10.3390/polym14091759.
4
Hydrophobic association and solvation of neopentane in urea, TMAO and urea-TMAO solutions.正戊烷在脲、TMAO 和脲-TMAO 溶液中的疏水缔合和溶剂化。
Phys Chem Chem Phys. 2022 Mar 16;24(11):6941-6957. doi: 10.1039/d1cp05321c.
5
Structure-based engineering of a short-chain cis-prenyltransferase to biosynthesize nonnatural all-cis-polyisoprenoids: molecular mechanisms for primer substrate recognition and ultimate product chain-length determination.基于结构的短链顺式-法尼基转移酶工程化以生物合成非天然全顺式聚异戊二烯:引物底物识别和最终产物链长决定的分子机制。
FEBS J. 2022 Aug;289(15):4602-4621. doi: 10.1111/febs.16392. Epub 2022 Feb 22.
6
CHARMM-GUI Polymer Builder for Modeling and Simulation of Synthetic Polymers.用于建模和模拟合成聚合物的 CHARMM-GUI 聚合物生成器。
J Chem Theory Comput. 2021 Apr 13;17(4):2431-2443. doi: 10.1021/acs.jctc.1c00169. Epub 2021 Apr 2.
7
The Role of Non-Rubber Components on Molecular Network of Natural Rubber during Accelerated Storage.非橡胶组分在天然橡胶加速储存过程中对分子网络的作用
Polymers (Basel). 2020 Nov 30;12(12):2880. doi: 10.3390/polym12122880.
8
Free energy of hydrophilic and hydrophobic pores in lipid bilayers by free energy perturbation of a restraint.通过约束自由能摄动计算脂质双层亲水和疏水孔的自由能。
J Chem Phys. 2020 Aug 7;153(5):054101. doi: 10.1063/5.0016682.
9
Progressive Hydrophobicity of Fluorobenzenes.氟苯的渐进疏水性。
J Phys Chem B. 2019 Nov 27;123(47):10083-10088. doi: 10.1021/acs.jpcb.9b08057. Epub 2019 Nov 18.
10
Structural Analysis of the Terminal Groups in Commercial Hevea Natural Rubber by 2D-NMR with DOSY Filters and Multiple-WET Methods Using Ultrahigh-Field NMR.采用超高场 NMR 结合 DOSY 滤波器和多 WET 方法的 2D-NMR 对商用天然橡胶末端基团的结构分析
Biomacromolecules. 2019 Mar 11;20(3):1394-1400. doi: 10.1021/acs.biomac.8b01771. Epub 2019 Feb 26.