轻松制备具有超疏水和高透光率的半结晶生物基聚碳酸酯

IF 4.1 2区化学 Q2 POLYMER SCIENCE

Polymer Pub Date : 2024-10-26 DOI:10.1016/j.polymer.2024.127729

Yiwen Zhang , Chenhao Li , Hao Wang , Zhao Yang , Wentao Zhang , Zhencai Zhang , Ruixia Liu , Fei Xu

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引用次数: 0

摘要

开发兼具超疏水特性和高透光率的材料是一项重大挑战。在这项研究中，羟基封端聚二甲基硅氧烷（HT-PDMS）和异山梨醇（ISB）通过一步聚合生成了共价键合的光学聚碳酸酯材料。通过溶剂触发工艺诱导形成微毛细管和莲花状纳米结构，我们显著增强了 "气垫 "效应，实现了约 5-7 μm 的结构尺度。这使得水接触角达到 157°，同时保持了 90% 以上的透光率。这些结构均匀地分布在整个聚合物基体中，与纯异山梨醇聚碳酸酯相比，断裂拉伸强度提高了 500%，最大强度超过 50 兆帕。这些多功能材料在智能窗户、太阳能电池板、相机镜头和其他光电设备中的应用前景广阔。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Facile fabrication of hemicrystalline bio-based polycarbonate with superhydrophobic and high transmittance

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Facile fabrication of hemicrystalline bio-based polycarbonate with superhydrophobic and high transmittance

Developing materials that combine superhydrophobic properties with high optical transmittance poses a significant challenge. In this study, hydroxyl-terminated polydimethylsiloxane (HT-PDMS) and isosorbide (ISB) were polymerized in a single step to create a covalently bonded optical polycarbonate material. By inducing the formation of micro-papillary and lotus-shaped nanoscale structures via a solvent-triggered process, we significantly enhanced the “air cushion” effect, achieving a structure scale of approximately 5–7 μm. This resulted in a water contact angle of 157° while maintaining over 90 % optical transmittance. The structures were uniformly distributed throughout the polymer matrix, leading to a 500 % increase in tensile strength at break compared to pure isosorbide polycarbonate, with a maximum strength exceeding 50 MPa. These multifunctional materials show great promise for applications in smart windows, solar panels, camera lenses, and other optoelectronic devices.

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来源期刊

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.