紫外线固化硫醇功能化硅氧烷弹性体的制备与表征,增强柔性基材的附着力

IF 5.5 Q1 ENGINEERING, CHEMICAL
Young-Hun Kim , Jongwon Kim , Jeong Ju Baek , Ki Cheol Chang , Baek Soo Park , Geun Yeol Bae , Won-Gun Koh , Gyojic Shin
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引用次数: 0

摘要

柔性可穿戴设备的快速发展增加了对具有出色弹性、生物相容性和透明度的基底材料的需求。聚二甲基硅氧烷(PDMS)因其优越的性能被广泛应用于这些领域。然而,其固有的低表面能限制了它在高拉伸性环境中的粘附性。为解决这一问题,人们开发了各种表面改性技术,但这些方法往往会改变 PDMS 的固有特性,或在制造过程中引入复杂性。本研究提出了基于紫外线(UV)固化硅氧烷树脂的弹性体,这种弹性体既能保持出色的柔韧性和透明度,又能显著提高粘附性能。研究人员合成了紫外线固化硅氧烷来制备弹性体,并与 PDMS 进行了机械、热和表面性能的对比评估。结果表明,所制备的弹性体可在紫外线照射下快速固化,在 25 °C 和 100 °C 时的储存模量分别比 PDMS 高出 6 倍和 37 倍。此外,热导率提高了 60%,热膨胀系数降低了 26%,在各种条件下均表现出卓越的机械稳定性。粘附性能也明显增强,剥离测试粘附强度是传统 PDMS 的 7 倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Fabrication and characterization of UV-curable thiol-functionalized siloxane elastomers with enhanced adhesion for flexible substrates

Fabrication and characterization of UV-curable thiol-functionalized siloxane elastomers with enhanced adhesion for flexible substrates
The rapid advancement of flexible and wearable devices has increased the demand for substrate materials with excellent elasticity, biocompatibility, and transparency. Polydimethylsiloxane (PDMS) is widely used in these applications due to its advantageous properties. However, its inherently low surface energy limits its adhesion in high-stretchability contexts. To address this issue, various surface modification techniques have been developed, but these methods often alter the intrinsic properties of PDMS or introduce complexities in the manufacturing process. This study proposes elastomers based on ultraviolet (UV)-curable siloxane resins, which retain outstanding flexibility and transparency while significantly enhancing adhesion properties. UV-curable siloxanes were synthesized to prepare elastomers that were evaluated for their mechanical, thermal, and surface properties in comparison with PDMS. Results indicate that the prepared elastomers can be rapidly cured under UV exposure, achieving storage moduli 6 and 37 times higher than those of PDMS at 25 °C and 100 °C, respectively. Furthermore, thermal conductivity improved by 60 %, and the coefficient of thermal expansion was reduced by 26 %, demonstrating superior mechanical stability across diverse conditions. Adhesion properties were also markedly enhanced, as shown by peel-test adhesion strength that was 7 times greater than that of conventional PDMS.
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来源期刊
Chemical Engineering Journal Advances
Chemical Engineering Journal Advances Engineering-Industrial and Manufacturing Engineering
CiteScore
8.30
自引率
0.00%
发文量
213
审稿时长
26 days
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