Solar Light-Driven Molecular Oxygen Activation by BiOCl Nanosheets: Synergy of Coexposed {001}, {110} Facets and Oxygen Vacancies

Ali, Sk Afsar; Sarkar, Sunny; Patra, Astam K.

doi:10.1021/acsami.4c06647

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.4c06647

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Solar Light-Driven Molecular Oxygen Activation by BiOCl Nanosheets: Synergy of Coexposed {001}, {110} Facets and Oxygen Vacancies

Sk Afsar Ali,

Sunny Sarkar,

Astam K. Patra

Abstract: Single-crystalline BiOCl nanosheets with coexposed {001} and {110} facets, as well as oxygen vacancies, were synthesized using a simple method. These nanosheets have the ability to activate molecular oxygen, producing reactive superoxide radicals (77.8%) and singlet oxygen (22.2%) when exposed to solar light. The BiOCl demonstrated excellent photocatalytic efficiency in producing H 2 O 2 under simulated solar light and in oxidatively hydroxylating phenylboronic acid under blue LED light. Our research highlight… Show more

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Cited by 2 publications

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Hierarchical Bifunctional NiO Electrocatalyst: Highly Porous Structure Boosting the Water Splitting Activity

Sarkar,

Ali,

Sarkar

et al. 2024

Chemistry An Asian Journal

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The development of an efficient, low‐cost and earth‐abundant electrocatalyst for water splitting is crucial for the production of sustainable hydrogen energy. However their practical applications are largely restricted by their limited synthesis methods, large overpotential and low surface area. Hierarchical materials with a highly porous three‐dimensional nanostructure have garnered significant attention due to their exceptional electrocatalytic properties. These hierarchical porous frameworks enable the fast electron transfer, rapid mass transport, and high density of unsaturated metal sites and maximize product selectivity. Here the process involved obtaining monodispersed microrod‐shaped Ni(OH)2 through a hydrothermal reaction, followed by a heat treatment to convert it into hierarchical microrod‐shaped NiO materials. N2 sorption analysis revealed that the BET surface area increased from 9 to 89 m2/g as a result of the heat treatment. The hierarchical microrod‐shaped NiO materials demonstrated outstanding bifunctional electrocatalytic water splitting capabilities, excelling in both HER and OER in basic solution. Overpotential of 347 mV is achieved at 10 mA/cm2 for OER activity, with a Tafel slope of 77 mV/dec. Similarly, overpotential of 488 mV is achieved at 10 mA/cm2 for HER activity, with a Tafel slope of 62 mV/dec.

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Hierarchical Bifunctional NiO Electrocatalyst: Highly Porous Structure Boosting the Water Splitting Activity

Sarkar,

Ali,

Sarkar

et al. 2024

Chemistry An Asian Journal

View full text Add to dashboard Cite

show abstract

Construction of nitrogen-doped graphene/BiOCl Schottky heterojunction for efficient photocatalytic degradation and CO2 reduction

Ding,

Hu,

Nie

et al. 2025

Environmental Research

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Solar Light-Driven Molecular Oxygen Activation by BiOCl Nanosheets: Synergy of Coexposed {001}, {110} Facets and Oxygen Vacancies

Cited by 2 publications

References 68 publications

Hierarchical Bifunctional NiO Electrocatalyst: Highly Porous Structure Boosting the Water Splitting Activity

Hierarchical Bifunctional NiO Electrocatalyst: Highly Porous Structure Boosting the Water Splitting Activity

Construction of nitrogen-doped graphene/BiOCl Schottky heterojunction for efficient photocatalytic degradation and CO2 reduction

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