可靠性(半导体)
计算机科学
能量(信号处理)
接口(物质)
储能
嵌入式系统
信号(编程语言)
工作(物理)
系统集成
机器人
工程类
鉴定(生物学)
高效能源利用
瞬态(计算机编程)
实时计算
钥匙(锁)
机器人学
降级(电信)
构造(python库)
控制工程
热能
控制系统
对象(语法)
能源消耗
信号处理
热的
作者
Xiangyang Li,X. Zheng,Chunlong Dai,Qun Niu,Xuting Jin,Ying Wang,Zhiao Zheng,Jieliang Zhao,Xin Li,Yang Zhao
标识
DOI:10.1002/adma.202520257
摘要
ABSTRACT Highly integrated devices that combine energy storage with multi‐functional sensing capabilities are pivotal for advancing the practical implementation of intelligent microsystems. However, their development is often hindered by inefficient manufacturing, reliability degradation stemming from interfacial mismatches, and challenges in achieving high‐performance, interference‐free operation. Herein, we demonstrate an ultrafast and efficient strategy to construct a monolithic multifunctional sensing and energy storage system via the Joule heating effect. This strategy enables seamless integration of all components within 8 s, intrinsically mitigating interfacial incompatibility and signal interference. Through the instantaneous thermal activation, the energy storage unit of anode‐free Zn‐ion micro‐battery delivers a capacity of 850 µAh cm −2 and energy density of 1060 µWh cm −2 , superior to most reported aqueous Zn‐based micro‐batteries. With a rapid charging time of 150 s, it powers the integrated device for over 6 h, achieving an impressive 24–h standby under low‐current conditions after full charge. Furthermore, this flexible monolithic system can be directly integrated into unmanned systems such as robotic arms, enabling autonomous environmental perception and adaptive decision‐making via machine learning, with object identification and classification accuracy exceeding 99%. This work paves the way for next‐generation autonomous microrobots, smart healthcare, and human‐machine interfaces.
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