New sustainable and environmental friendly process of synthesis of highly porous Mo2S3 nanoflowers in cooking oil and their electrochemical properties

In the present study, a novel eco-friendly approach for the synthesis of hierarchically porous Mo2S3 nanoflowers in cooking oil have been developed. This approach enables us to stabilize high temperature phase of Mo2S3 even at 150 °C under hydrothermal condition in the environmentally benign solvent...

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Veröffentlicht in:	Electrochimica acta 2019-03, Vol.300, p.177-185
Hauptverfasser:	Nishanthi, S.T., Yadav, Krishna Kumar, Baruah, Arabinda, Ganguli, Ashok K., Jha, Menaka
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Sprache:	eng
Schlagworte:	Cooking Cooking oil Electrochemical analysis Electrodes Flux density High temperature Low temperature Molybdenum (III) sulfide Sodium sulfate Specific capacitance Surface area Synthesis
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creator	Nishanthi, S.T. Yadav, Krishna Kumar Baruah, Arabinda Ganguli, Ashok K. Jha, Menaka
description	In the present study, a novel eco-friendly approach for the synthesis of hierarchically porous Mo2S3 nanoflowers in cooking oil have been developed. This approach enables us to stabilize high temperature phase of Mo2S3 even at 150 °C under hydrothermal condition in the environmentally benign solvent for the first time. The above low temperature approach leads to the formation of Mo2S3 nanoflowers (diameter 0.5–2.0 μm and leaf thickness of ∼10 nm). Further electrochemical studies shows that the as-synthesized Mo2S3 electrode shows high specific capacitance ∼248 F/g at a current density of 1 mA/g in Na2SO4 electrolyte. The Mo2S3 electrode showed high power and energy density of ∼15.98 kWkg−1 and ∼98.7 Whkg−1 respectively. Also, the Mo2S3 electrode shows good electrochemical stability up to 3000 cycles. Thus from the above study, we have shown that the possibility of stabilization of metal chalcogenide in cooking oil and shown its high performance supercapacitors applications.
doi_str_mv	10.1016/j.electacta.2019.01.091
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subjects	Cooking Cooking oil Electrochemical analysis Electrodes Flux density High temperature Low temperature Molybdenum (III) sulfide Sodium sulfate Specific capacitance Surface area Synthesis
title	New sustainable and environmental friendly process of synthesis of highly porous Mo2S3 nanoflowers in cooking oil and their electrochemical properties
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