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W3036793281 endingPage "155690" @default.
W3036793281 startingPage "155690" @default.
W3036793281 abstract "Abstract Recently, 2D materials are being explored as attractive candidate materials for mechanical energy harvesting by employing the triboelectric effect. However, in this work, development of flexible paper-based triboelectric nanogenerators has been reported in 2-, 5- and 9-layered MoS2 nanosheets (MNSs). The syntheses of bilayered MNSs have been carried out by using a rarely reported natural surfactant (aqueous extract of Washnut, viz.) assisted simple bath ultrasonication process. The development of triboelectric power cells (TPCs) by using bilayer MNSs has also not been reported earlier and it has been found that it is exhibiting the best performance. The maximum values of open-circuit voltage (Voc) and power density of ∼10.20 V and ∼2.55 mW/m2, respectively, are obtained in bilayer MNSs based TPC. It is found that the fabricated device can charged up an external capacitor up to the maximum voltage of 0.52 V within 25s. Also, due to the highest absorbance of bilayer MNSs in the visible region, it has been found to be acting as the most effective photocatalytic material for removal of MB dye from water even under the visible light excitation. In another experiment, the bilayer MNSs is found to be exhibiting superior catalytic activity in the hydrogen evolution reaction (HER), and the highest value of the Tafel slope for bilayer MNSs is obtained as ∼49 mV/decade. Thus, it is envisioned that this work will open up new vistas of easy and eco-friendly processes for synthesis of 2D MoS2 nanosheets for their potential applications in energy harvesting by using triboelectric and as well as catalytic processes." @default.
W3036793281 created "2020-06-25" @default.
W3036793281 creator A5075637556 @default.
W3036793281 creator A5089700622 @default.
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W3036793281 creator A5091846630 @default.
W3036793281 date "2020-12-01" @default.
W3036793281 modified "2023-10-01" @default.
W3036793281 title "Synthesis of bilayer MoS2 nanosheets by green chemistry approach and its application in triboelectric and catalytic energy harvesting" @default.
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W3036793281 doi "https://doi.org/10.1016/j.jallcom.2020.155690" @default.
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