Unlocking high-efficiency energy storage and conversion with biocompatible electrodes: the key role of interfacial interaction assembly and structural design†

IF 3.2 Q2 CHEMISTRY, PHYSICAL
Energy advances Pub Date : 2024-08-07 DOI:10.1039/D4YA00387J
Jeongyeon Ahn, Hyeseoung Lim, Jongkuk Ko and Jinhan Cho
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Abstract

Biocompatible electrodes, situated at the intersection of bioelectronics and soft electronics, hold the promise of groundbreaking advancements in human–machine interaction and bio-inspired applications. Their development relies on achieving stable, robust deposition of electrically and/or electrochemically active components on biocompatible substrates, ensuring operational stability under various mechanical stresses. However, despite notable progress, most biocompatible electrodes still struggle to simultaneously achieve high mechanical flexibility, electrical conductivity, electrochemical activity, and long-term stability at the same time. These challenges present critical barriers to the development of more advanced biocompatible devices, particularly in the field of energy storage and conversion. The key lies in optimizing the complementary interfacial interactions between active components (i.e., electrical and/or electrochemical components) and biocompatible substrates, and between adjacent active components, as well as in the structural design of the electrodes. In this perspective, we review recent approaches for preparing textile- and hydrogel-based biocompatible electrodes that can achieve high electrical conductivity without compromising favorable properties of biocompatible substrates (i.e., textile and hydrogel) for energy storage and conversion devices. In particular, we highlight the critical role of the interfacial interactions between electrode components and demonstrate how these interactions significantly enhance the energy performance and operational stability.

Abstract Image

利用生物兼容电极实现高效能量存储和转换:界面相互作用组装和结构设计的关键作用
生物兼容电极位于生物电子学和软电子学的交叉点,有望在人机交互和生物启发应用领域取得突破性进展。它们的开发有赖于在生物相容性基底上实现稳定、坚固的电和/或电化学活性成分沉积,确保在各种机械应力下的运行稳定性。然而,尽管取得了显著进展,大多数生物兼容电极仍难以同时实现高机械灵活性、导电性、电化学活性和长期稳定性。这些挑战为开发更先进的生物兼容设备,尤其是能源存储和转换领域的设备,设置了关键的障碍。关键在于优化活性成分(即电和/或电化学活性成分)与生物兼容基底之间、相邻活性成分之间以及电极结构设计中的互补界面相互作用。在这一视角中,我们首先回顾了用于能量存储和转换设备的生物兼容电极的最新进展,并探讨了在显著提高性能方面仍然存在的挑战。我们特别强调了电极元件之间界面相互作用的关键作用,并展示了这些相互作用如何显著提高能量性能和运行稳定性。
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来源期刊
CiteScore
1.80
自引率
0.00%
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