聚偏氟乙烯
材料科学
膜
透气比表面积
防水
静电纺丝
多孔性
复合材料
纳米纤维
数码产品
纳米技术
聚合物
工程类
电气工程
遗传学
图层(电子)
生物
作者
Byungwook Youn,Yangyul Ju,Doojin Lee,Je Sung Youm,Yun Mi So,Seung Hoon Lee,Chan Kim,Yoong Ahm Kim
出处
期刊:ACS Nano
[American Chemical Society]
日期:2024-08-20
卷期号:18 (35): 24532-24540
被引量:5
标识
DOI:10.1021/acsnano.4c08750
摘要
Advancements in electronic devices demand materials capable of exceptional performance in various challenging environments. This study presents polyvinylidene fluoride (PVDF) nonwoven membranes with controlled porosity, created using an air-guided electrospinning method, followed by a calendaring process. These membranes exhibit a combination of water-repellent properties and sound transmission capabilities, making them ideal candidates for use in air and acoustic vents in electronic systems. A key feature of our membrane is the three-dimensional nanostructured pores, ranging from 0.20 to 0.76 μm, with a mean pore size of 0.51 μm, achieved through the formation of randomly arranged long nanofibers. By employing both experimental and theoretical methods, we achieved impressive performance metrics: air permeability of 0.86 cm3/cm2/s, water contact angles up to 139.3°, and breakthrough pressure as low as 0.27 MPa. Our PVDF nonwoven membranes maintain an optimal balance of stiffness, density, and air permeability, leading to exceptionally low sound transmission loss values ranging between -10 and -40 dBV/Pa, all while preserving their structural integrity. These findings contribute to the development of next-generation waterproof and acoustically permeable membranes, offering enhanced performance capabilities in demanding operational scenarios. This work advances the field of nanomaterials, environmental engineering, and acoustic technologies, with the potential to influence the design of future electronic devices.
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