Ultra-high stretchability and shape fixation rate shape memory polyurethanes based on cyclic polytetrahydrofuran molecular rings

IF 4.1 2区 化学 Q2 POLYMER SCIENCE
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Abstract

Chemical cross-linking is commonly used to prevent slippage between molecular chains in shape memory polymers (SMPs) to improve shape return. However, chemical cross-linking makes SMPs less stretchable, and the disordered network structure reduces the ability of SMPs to maintain temporary shapes. To obtain ultra-high stretchability and better shape memory properties, a cyclic polymer (C-PTHF-OH) was introduced into the shape memory polyurethane (PUCX) network, and the PUCX network topology was controlled by adjusting the content of C-PTHF-OH molecular rings. PUC0.5 exhibited the highest shape fixation (99.9 %) and shape recovery (98.4 %), and the higher the content of the C-PTHF-OH molecular ring, the higher the elongation at break of the prepared PUCX, with a slight decrease in tensile strength. Compared to PUC0 (2000 % elongation at break and 32 MPa tensile strength) prepared from the linear polymer, PUC0.5 showed up to 2150 % elongation at break and 31 MPa tensile strength. This study provides new ideas for the design of network structures for SMPs and is a new paradigm introduced into the SMPs network by cyclic topological polymers.

Abstract Image

基于环状聚四氢呋喃分子环的超高拉伸性和形状固定率形状记忆聚氨酯
化学交联通常用于防止形状记忆聚合物(SMP)分子链之间的滑动,以改善形状恢复。然而,化学交联会降低 SMP 的拉伸性,无序的网络结构也会降低 SMP 保持临时形状的能力。为了获得超高拉伸性和更好的形状记忆特性,在形状记忆聚氨酯(PUC)网络中引入了环状聚合物(C-PTHF-OH),并通过调整 C-PTHF-OH 分子环的含量来控制 PUC 网络的拓扑结构。PUC 的形状固定率(99.9%)和形状恢复率(98.4%)最高,C-PTHF-OH 分子环的含量越高,制备的 PUC 的断裂伸长率越高,但拉伸强度略有下降。与线性聚合物制备的 PUC(断裂伸长率为 2000 %,拉伸强度为 32 兆帕)相比,PUC 的断裂伸长率高达 2150 %,拉伸强度为 31 兆帕。这项研究为 SMP 网络结构的设计提供了新思路,是循环拓扑聚合物引入 SMP 网络的新范例。
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来源期刊
Polymer
Polymer 化学-高分子科学
CiteScore
7.90
自引率
8.70%
发文量
959
审稿时长
32 days
期刊介绍: Polymer is an interdisciplinary journal dedicated to publishing innovative and significant advances in Polymer Physics, Chemistry and Technology. We welcome submissions on polymer hybrids, nanocomposites, characterisation and self-assembly. Polymer also publishes work on the technological application of polymers in energy and optoelectronics. The main scope is covered but not limited to the following core areas: Polymer Materials Nanocomposites and hybrid nanomaterials Polymer blends, films, fibres, networks and porous materials Physical Characterization Characterisation, modelling and simulation* of molecular and materials properties in bulk, solution, and thin films Polymer Engineering Advanced multiscale processing methods Polymer Synthesis, Modification and Self-assembly Including designer polymer architectures, mechanisms and kinetics, and supramolecular polymerization Technological Applications Polymers for energy generation and storage Polymer membranes for separation technology Polymers for opto- and microelectronics.
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