Khushali Joshi scite author profile

Khushali Joshi

2Publications

5Citation Statements Received

126Citation Statements Given

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125

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Pandit Deendayal Petroleum University

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MoS₂ Nanostructures for Solar Hydrogen Generation via Membraneless Electrochemical Water Splitting

Joshi

Mistry

Tripathi

et al. 2023

ACS Appl. Electron. Mater.

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Storing and delivering green hydrogen generated by solar energy have the potential to significantly supplement and disburse the share of promising but intermittent renewable energy. In this scenario, robust materials capable of delivering solar-driven electrochemical water splitting for hydrogen generation provide an interesting protocol that is applicable to all sectors of energy. Electrochemical water splitting is the conventional and most prevalent technique for hydrogen generation, which utilizes platinum-based materials for the hydrogen evolution reaction (HER). However, these platinum-based noble metal catalysts possess poor cyclic stability, limiting their commercial application for economical hydrogen generation. Therefore, the development of efficient non-noble metal-based electrocatalysts is urgently needed to produce cost-competitive hydrogen energy. Several kinds of non-noble metal-based heterogeneous electrocatalysts, including carbides, sulfides, selenides, oxides, and phosphides, have been developed and studied. The unique physicochemical properties of carbonaceous materials make them promising candidates to support catalysts. In this paper, molybdenum disulfide (MoS2) nanomaterial catalysts have been synthesized, deposited on carbon fiber (CF)-based materials, and then used for solar hydrogen generation by membraneless electrochemical water splitting. At 430 W/m2 irradiation and 35 °C working temperature, the solar-to-hydrogen conversion efficiency is found to be 2.46%.

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Solar Hydrogen Generation using Abundant Materials via Membrane-less Electrochemical Water Splitting

Joshi

Mistry

Tripathi

et al. 2022

Preprint

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Storing and delivering green hydrogen produced using solar energy possess exceptional potential to supplement and dispense the share of promising but sporadic renewable energy. In this scenario, robust materials capable of delivering solar driven electrochemical water splitting for hydrogen generation provide intriguing protocol that are applicable to all sectors of energy., Electrochemical water splitting is conventional and most prevalent technique for hydrogen generation, which utilizes platinum-based materials for hydrogen evolution reaction (HER). However, these palatinum based noble metal catalysts possess poor cyclic stability limiting its commercial application for economical hydrogen generation. Therefore, development of efficient non-noble metal based electro-catalysts are urgently needed to produce cost-competitive hydrogen energy. Several kinds of non-noble metal based heterogeneous electro-catalysts, including carbides, sulphides, selenides, oxides, and phosphides have been developed and studied. Unique physicochemical properties of carbon materials make them promising candidates to support catalysts. In this paper, molybdenum disulphide (MoS2) nanomaterial catalysts have been synthesized, deposited on carbon fibre (C-fibre) based material and then used for solar hydrogen generation by membrane-less electrochemical water splitting. Solar to hydrogen conversion efficiency is found to be 2.46% at an irradiation level of 430 W/m2 and working temperature of 35°C.

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Khushali Joshi

MoS₂ Nanostructures for Solar Hydrogen Generation via Membraneless Electrochemical Water Splitting

Solar Hydrogen Generation using Abundant Materials via Membrane-less Electrochemical Water Splitting

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Khushali Joshi

MoS2 Nanostructures for Solar Hydrogen Generation via Membraneless Electrochemical Water Splitting

Solar Hydrogen Generation using Abundant Materials via Membrane-less Electrochemical Water Splitting

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Resources

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MoS₂ Nanostructures for Solar Hydrogen Generation via Membraneless Electrochemical Water Splitting