Durable superhydrophobic surface in wearable sensors: From nature to application

Ziyi Dai, Ming Lei, Sen Ding, Qian Zhou, Bing Ji, Mingrui Wang, Bingpu Zhou
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Abstract

The current generation of wearable sensors often experiences signal interference and external corrosion, leading to device degradation and failure. To address these challenges, the biomimetic superhydrophobic approach has been developed, which offers self-cleaning, low adhesion, corrosion resistance, anti-interference, and other properties. Such surfaces possess hierarchical nanostructures and low surface energy, resulting in a smaller contact area with the skin or external environment. Liquid droplets can even become suspended outside the flexible electronics, reducing the risk of pollution and signal interference, which contributes to the long-term stability of the device in complex environments. Additionally, the coupling of superhydrophobic surfaces and flexible electronics can potentially enhance the device performance due to their large specific surface area and low surface energy. However, the fragility of layered textures in various scenarios and the lack of standardized evaluation and testing methods limit the industrial production of superhydrophobic wearable sensors. This review provides an overview of recent research on superhydrophobic flexible wearable sensors, including the fabrication methodology, evaluation, and specific application targets. The processing, performance, and characteristics of superhydrophobic surfaces are discussed, as well as the working mechanisms and potential challenges of superhydrophobic flexible electronics. Moreover, evaluation strategies for application-oriented superhydrophobic surfaces are presented.

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可穿戴传感器中的耐用超疏水表面:从自然到应用
目前的可穿戴传感器经常会受到信号干扰和外部腐蚀,从而导致设备退化和失效。为了应对这些挑战,人们开发了仿生物超疏水方法,这种方法具有自清洁、低附着力、耐腐蚀、抗干扰等特性。这种表面具有分层纳米结构和低表面能,因此与皮肤或外部环境的接触面积较小。液滴甚至可以悬浮在柔性电子元件外部,降低污染和信号干扰的风险,这有助于设备在复杂环境中的长期稳定性。此外,超疏水表面和柔性电子元件的耦合有可能提高设备的性能,因为它们具有较大的比表面积和较低的表面能。然而,分层纹理在各种情况下的脆弱性以及标准化评估和测试方法的缺乏限制了超疏水可穿戴传感器的工业化生产。本综述概述了超疏水柔性可穿戴传感器的最新研究,包括制造方法、评估和具体应用目标。文章讨论了超疏水表面的加工、性能和特点,以及超疏水柔性电子器件的工作机制和潜在挑战。此外,还介绍了面向应用的超疏水表面的评估策略。
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CiteScore
17.20
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Issue Information Back Cover: High-yield upcycling of feather wastes into solid-state ultra-long phosphorescence carbon dots for advanced anticounterfeiting and information encryption (EXP2 6/2024) Frontispiece: Advancements and challenges in brain cancer therapeutics (EXP2 6/2024) Front Cover: Piezoelectric stimulation enhances bone regeneration in alveolar bone defects through metabolic reprogramming of macrophages (EXP2 6/2024) Pioneering Exploration for a lasting and sustainable future
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