Hydrophobic, elastic and conductive O-BC/MXene aerogel with high sensing performance

IF 3.5 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Yifan Tong, Linxiang Liu, Zehong Chen, Linxin Zhong
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Abstract

Hydrophobic, elastic, and conductive (HEC) aerogels have significant potential in electronic devices. Herein, we propose a new method to fabricate an HEC aerogel with excellent mechanical and sensing performances from TEMPO-oxidized bacterial cellulose (O-BC) and conductive MXene nanosheets via directional freeze-drying and silanization modification. O-BC with a high aspect ratio can interweave with each other to form continuous layers, while MXene can induce a regular and flat structure and provide good conductivity. The silanization modification ensures high hydrophobicity and high elasticity, which can prevent the aerogel from structural collapse by avoiding adhesion among lamellae. The resulting aerogel can withstand compressive strain high up to 90% and long-term compression for 10,000 cycles at 50% strain due to the elastic and hydrophobic lamellar structure. It also offers a precise electrical response to stress signals in a broad detection range of 0–40 kPa and can accurately detect biological signals from humans. These structural and mechanical performance benefits make the HEC aerogel valuable in the field of pressure sensing.

具有高传感性能的疏水性、弹性和导电性 O-BC/MXene 气凝胶
疏水、弹性和导电(HEC)气凝胶在电子设备中具有巨大潜力。在此,我们提出了一种新方法,利用 TEMPO 氧化细菌纤维素(O-BC)和导电 MXene 纳米片材,通过定向冷冻干燥和硅烷化改性,制备出具有优异机械和传感性能的 HEC 气凝胶。具有高纵横比的 O-BC 可以相互交织形成连续的层,而 MXene 则可以形成规则的平面结构并提供良好的导电性。硅烷化改性确保了气凝胶的高疏水性和高弹性,避免了薄片之间的粘连,从而避免了结构坍塌。由于气凝胶具有弹性和疏水性薄片结构,它能承受高达 90% 的压缩应变,并能在 50%应变下长期压缩 10,000 次。它还能在 0-40 kPa 的宽检测范围内对应力信号做出精确的电响应,并能准确检测人体生物信号。这些结构和机械性能优势使 HEC 气凝胶在压力传感领域具有重要价值。
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来源期刊
Journal of Materials Science
Journal of Materials Science 工程技术-材料科学:综合
CiteScore
7.90
自引率
4.40%
发文量
1297
审稿时长
2.4 months
期刊介绍: The Journal of Materials Science publishes reviews, full-length papers, and short Communications recording original research results on, or techniques for studying the relationship between structure, properties, and uses of materials. The subjects are seen from international and interdisciplinary perspectives covering areas including metals, ceramics, glasses, polymers, electrical materials, composite materials, fibers, nanostructured materials, nanocomposites, and biological and biomedical materials. The Journal of Materials Science is now firmly established as the leading source of primary communication for scientists investigating the structure and properties of all engineering materials.
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