Environmentally benign enhanced hydrogen production via lethal H sub(2)S under natural sunlight using hierarchical nanostructured bismuth sulfide

Nanorods and hierarchical nanostructures (dandelion flowers) of bismuth sulfide (Bi sub(2)S sub(3)) were synthesized using a solvothermal method. The effects of solvents such as water and ethylene glycol on the morphology and size of the Bi sub(2)S sub(3) nanostructures were studied. A structural st...

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Bibliographic Details
Published in:RSC advances 2014-10, Vol.4 (90), p.49295-49302
Main Authors: Kawade, U V, Panmand, R P, Sethi, YA, Kulkarni, M V, Apte, S K, Naik, S D, Kale, B B
Format: Article
Language:English
Subjects:
Evolution
Flowers
Hydrogen production
Nanorods
Nanostructure
Photocatalysis
Splitting
Sunlight
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Summary:Nanorods and hierarchical nanostructures (dandelion flowers) of bismuth sulfide (Bi sub(2)S sub(3)) were synthesized using a solvothermal method. The effects of solvents such as water and ethylene glycol on the morphology and size of the Bi sub(2)S sub(3) nanostructures were studied. A structural study showed an orthorhombic phase of Bi sub(2)S sub(3). We observed nanorods 30-50 nm in diameter and dandelion flowers assembled with these nanorods. A formation mechanism for the hierarchical nanostructures of Bi sub(2)S sub(3) is proposed. Based on the tuneable band gap of these nanostructures in the visible and near-IR regions, we demonstrated the photocatalytic production of hydrogen from H sub(2)S under normal sunlight. Abundantly available toxic H sub(2)S was used to produce hydrogen under normal sunlight conditions. We observed an excellent hydrogen production of 8.88 mmol g super(-1) h super(-1) under sunlight (on a sunny day between 11.30 am and 2.30 pm) for the Bi sub(2)S sub(3) flowers and 7.08 mmol g super(-1) h super(-1) for the nanorods. The hierarchical nanostructures suppress charge carrier recombination as a result of defects, which is ultimately responsible for the higher activity. The evolution of the hydrogen obtained is fairly stable when the catalyst is used repeatedly. The evolution of hydrogen viawater splitting was observed to be lower than that viaH sub(2)S splitting. Bi sub(2)S sub(3) was observed to be a good eco-friendly photocatalyst active under natural sunlight. The photo-response study showed that the Bi sub(2)S sub(3) microstructures are good candidates for applications in highly sensitive photo-detectors and photo-electronic switches.
ISSN:2046-2069
DOI:10.1039/c4ra07143c