Binder-less MnO2 nanosheets as energy storage electrode for the piezoelectric mediated self-charging electrochemical supercapacitor

IF 8.2 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Today Nano Pub Date : 2025-07-22 DOI:10.1016/j.mtnano.2025.100659

Parthiban Pazhamalai , Vigneshwaran Mohan , Vimal Kumar Mariappan , Rajavarman Swaminathan , Sang-Jae Kim

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Abstract

Integrated energy systems are of great interest as it couples the both the energy harnessing and storage onto a single sustainable component for the practical IoT applications. In this work, we demonstrated the integration of energy storage and harnessing in a single component system which can be charged via bio-mechanical force. The integrated self-charging supercapacitor (ISCS) is fabricated with the aid of electrochemically deposited MnO₂ and ionogelled electrospun PVDF nanofibrous mat as piezoelectric separator. The self-charging characteristics of the MnO₂/CC ISCS is studied under various applied force with the highest charging voltage of 490 mV. The self-charging mechanism of the MnO₂/CC ISCS is explained via piezoelectrochemical phenomenon. This study highlights the usage of binder free electrode for the self-charging supercapacitor which will enhance the energy conversion and storage process over the binder-based devices. Overall, the results provide a new insight in fabrication of binder free electrodes, which might lead to enhanced performance considering the state of the art of self-charging supercapacitors.

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无粘结剂二氧化锰纳米片作为压电介质自充电电化学超级电容器的储能电极

集成能源系统非常有趣，因为它将能源利用和存储耦合到实际物联网应用的单个可持续组件上。在这项工作中，我们展示了能量存储和利用在一个单一组件系统中的集成，该系统可以通过生物机械力充电。以电化学沉积二氧化锰和电纺丝PVDF纳米纤维垫为压电隔膜制备了集成自充电超级电容器（ISCS）。在最高充电电压为490 mV的条件下，研究了MnO2/CC ISCS在不同作用力下的自充电特性。通过压电电化学现象解释了MnO2/CC ISCS的自充电机理。本研究强调了无粘结剂电极在自充电超级电容器中的应用，与基于粘结剂的装置相比，它将提高能量转换和存储过程。总的来说，研究结果为无粘结剂电极的制造提供了新的见解，考虑到目前自充电超级电容器的现状，这可能会提高性能。

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来源期刊

Materials Today Nano Multiple-

CiteScore

11.30

自引率

3.90%

发文量

130

审稿时长

31 days

期刊介绍： Materials Today Nano is a multidisciplinary journal dedicated to nanoscience and nanotechnology. The journal aims to showcase the latest advances in nanoscience and provide a platform for discussing new concepts and applications. With rigorous peer review, rapid decisions, and high visibility, Materials Today Nano offers authors the opportunity to publish comprehensive articles, short communications, and reviews on a wide range of topics in nanoscience. The editors welcome comprehensive articles, short communications and reviews on topics including but not limited to: Nanoscale synthesis and assembly Nanoscale characterization Nanoscale fabrication Nanoelectronics and molecular electronics Nanomedicine Nanomechanics Nanosensors Nanophotonics Nanocomposites