Interface charge density modulation of a lamellar-like spatially separated Ni₉S₈ nanosheet/Nb₂O₅ nanobelt heterostructure catalyst coupled with nitrogen and metal (M = Co, Fe, or Cu) atoms to accelerate acidic and alkaline hydrogen evolution reactions

Sundaram Chandrasekaran, Na Li, Yang Zhuang, Lijun Sui, Zhizhong Xiao, Dayong Fan, Vanchiappan Aravindan, Chris Bowen, Huidan Lu, Yongping Liu

University of Bath
Department of Mechanical Engineering
Centre for Sustainable Chemical Technologies (CSCT)
Centre for Nanoscience and Nanotechnology
EPSRC Centre for Doctoral Training in Statistical Applied Mathematics (SAMBa)
Institute for Mathematical Innovation (IMI)
Faculty of Engineering and Design
Centre for Integrated Materials, Processes & Structures (IMPS)

Guilin University of Technology
Tongji University
Indian Institute of Science Education and Research (IISER), Tirupati
University of Bath

Research output: Contribution to journal › Article › peer-review

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Interface charge density modulation of a lamellar-like spatially separated Ni₉S₈ nanosheet/Nb₂O₅ nanobelt heterostructure catalyst coupled with nitrogen and metal (M = Co, Fe, or Cu) atoms to accelerate acidic and alkaline hydrogen evolution reactions

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Interface charge density modulation of a lamellar-like spatially separated Ni9S8 nanosheet/Nb2O5 nanobelt heterostructure catalyst coupled with nitrogen and metal (M = Co, Fe, or Cu) atoms to accelerate acidic and alkaline hydrogen evolution reactions

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Engineering

Chemical Engineering

Material Science

Interface charge density modulation of a lamellar-like spatially separated Ni₉S₈ nanosheet/Nb₂O₅ nanobelt heterostructure catalyst coupled with nitrogen and metal (M = Co, Fe, or Cu) atoms to accelerate acidic and alkaline hydrogen evolution reactions