Yanbing Ren
Northwest University (China)
8 Papers
2 Citations
Yanbing Ren is an academic researcher from Northwest University (China). The author has contributed to research in topics: Graphyne & Heterojunction. The author has an hindex of 4, co-authored 8 publications.
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Papers
Charge separation and strong adsorption-enhanced MoO3 visible light photocatalytic performance
Guan Xin,Yanbing Ren,Sifan Chen,Junfeng Yan,Gang Wang,Zhao Hongyi,Wu Zhao,Zhiyong Zhang,Zhouhu Deng,Yunyao Zhang,Yang Dai,Leideng Zou,Ruiyong Chen,Chunli Liu +13 more
TL;DR: In this article, the photocatalytic properties of α-MoO3 nanorods and hexagonal prism were successfully synthesized via a facile hydrothermal method, and the results showed that the products are very pure with excellent morphology.
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Tunable type-I/type-II transition in g-C3N4/graphyne heterostructure by BN-doping: A promising photocatalyst
Jiangni Yun,Jiangni Yun,Yanni Zhang,Yanbing Ren,Peng Kang,Junfeng Yan,Wu Zhao,Zhiyong Zhang,Hong Guo +8 more
TL;DR: In this paper, a comprehensive theoretical study of interfacial properties of g-C3N4/Gyne heterostructure including the band structure, partial density of state, optical absorption, wave functions, charge density difference, band alignment and photocurrent density is acquired to provide deep insight into the photocatalytic performance.
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Tunable band gap of graphyne-based homo- and hetero-structures by stacking sequences, strain and electric field
TL;DR: The physical origin of the band gap variation under an electric field was unraveled using energy-band theory and valuable insight into two-dimensional vdW layered structures for use in next generation flexible nanoelectronics and optoelectronic devices is provided.
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Enhanced Optical Absorption and Interfacial Carrier Separation of CsPbBr3/Graphene Heterostructure: Experimental and Theoretical Insights.
Jiangni Yun,Jiangni Yun,Fan Haodong,Yanni Zhang,Huang Renjing,Yanbing Ren,Mingzhi Guo,An Huan,Peng Kang,Hong Guo +9 more
TL;DR: The calculated results reveal that, accounting for the presence of the stronger built-in electric field, larger band bending value and smaller effective mass, the PbBr2/graphene interface can realize the separation of the photoinduced carriers more effectively than CsBr/grapehene interface and thus more efficiently facilitate electron transfer from perovskite optical absorber side to graphene electronic transport side.
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