Photovoltaic and triboelectrification empowered light-weight flexible self-charging asymmetric supercapacitor cell for self-powered multifunctional electronics

Herein, we highlight the simplistic fabrication of a light-weight, flexible self-charging power pack by the prudent integration of two paper-based high-performance triboelectric nanogenerators (HPTENGs), one commercial semi-flexible photovoltaic/solar cell and a paper-based all-solid-state asymmetri...

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Published in:Renewable & sustainable energy reviews 2021-11, Vol.151, p.111595, Article 111595
Main Authors: Maitra, Anirban, Bera, Ranadip, Halder, Lopamudra, Bera, Aswini, Paria, Sarbaranjan, Karan, Sumanta Kumar, Si, Suman Kumar, De, Anurima, Ojha, Suparna, Khatua, Bhanu Bhusan
Format: Article
Language:English
Subjects:
Asymmetric-type supercapacitor
Controlled drug release
e-healthcare monitoring
Flexible
Photovoltaic cell
Self-charging
Triboelectric nanogenerators
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Summary:Herein, we highlight the simplistic fabrication of a light-weight, flexible self-charging power pack by the prudent integration of two paper-based high-performance triboelectric nanogenerators (HPTENGs), one commercial semi-flexible photovoltaic/solar cell and a paper-based all-solid-state asymmetric-type supercapacitor (ASSASC) with optimized performance. Each HPTENG unit comprises of a ~20 wt% barium titanate nanoparticles loaded surface micropatterned post-polled PDMS composite (PDMS–20BTO) film-strip impregnated with graphite coated Whatman® 41 filter paper (GFP) as negative and a polypyrrole electrodeposited GFP as positive triboelectric friction layers, respectively. Contrariwise, the ASSASC consists of a nickel-cobalt-molybdenum oxide–graphitic C3N4 hybrid composite coated GFP (NCMO–gCN2/GFP) as positive and a graphitic C3N4 modified reduced graphene oxide coated GFP (gCN–m–RGO/GFP) as negative electrodes, separated by a thin PVA–KOH gel-type electrolyte membrane. Finally, under deformations/stress and illumination of solar light individually on top of our photovoltaic and HPTENGs driven self-charging ASSASC (PTSCASC) power pack, it efficaciously generates electrical energy and consequently stores this generated energy as electrochemical energy for sustainable power supply. Our self-powered PTSCASC# power pack prototype (with two ASSASCs) has been effectually integrated with a medical smart patch for electric pulsatile mediated controlled drug release. Hence, our as-designed self-charging power pack possesses immense potentials for self-powered multifunctional electronics and smart e-healthcare monitoring systems. A light-weight, paper-based self-charging power pack was developed by the judicious integration of a commercial semi-flexible photovoltaic cell, two paper-based triboelectric nanogenerators, and one/two paper-based all-solid-state asymmetric supercapacitors with optimized output performances. The eco-friendly, flexible self-charging power pack exhibits admirable output performances which are indeed auspicious for the incessant operation of self-powered medical devices and multifunctional electronics. [Display omitted] •A light-weight, paper-based flexible self-charging power pack was developed.•The pack comprised of solar cell, triboelectric nanogenerators and supercapacitors.•The pack can be charged: electrically, through deformations or light illuminations.•The paper-based flexible power pack exhibits admirable self-charging performances
ISSN:1364-0321
1879-0690
DOI:10.1016/j.rser.2021.111595