Soochow University
China
The scientist’s investigation covers issues in Inorganic chemistry, Graphene, Electrochemistry, Nanoparticle and Nanotechnology. His Inorganic chemistry study incorporates themes from Heterogeneous catalysis, Nanostructure, X-ray photoelectron spectroscopy, Hematite and Absorption spectroscopy. His studies examine the connections between Electrochemistry and genetics, as well as such issues in Hybrid material, with regards to Sintering and Carbon nanotube.
His study on Nanoparticle also encompasses disciplines like
Jun Zhong mainly investigates Nanotechnology, Inorganic chemistry, Hematite, Photocurrent and Absorption spectroscopy. His Nanotechnology research incorporates elements of Electrochemistry and Anode. Jun Zhong interconnects Overpotential and Graphene in the investigation of issues within Inorganic chemistry.
His work deals with themes such as Hydrothermal circulation, Water splitting and Nanostructure, which intersect with Hematite. His Water splitting research is within the category of Photocatalysis. His Photocatalysis study combines topics from a wide range of disciplines, such as Photochemistry, Visible spectrum and Quantum efficiency.
His main research concerns Electrocatalyst, Nanoparticle, Photocurrent, Overpotential and Water splitting. His studies deal with areas such as Hydrogen evolution, Nanotechnology, Hydrogen production, Electrolysis of water and Oxygen evolution as well as Electrocatalyst. His work in Hydrogen production is not limited to one particular discipline; it also encompasses Photocatalysis.
His research investigates the connection with Photocurrent and areas like Hematite which intersect with concerns in Charge separation and Overlayer. Jun Zhong has included themes like Inorganic chemistry, Chemical state, Doping and Carbon nanotube in his Overpotential study. His Water splitting study combines topics in areas such as Coupling, Metal-organic framework and Nanostructure.
Jun Zhong focuses on Electrocatalyst, Hydrogen production, Chemical energy, Active site and X-ray absorption spectroscopy. Jun Zhong combines subjects such as Fe based, Oxygen evolution and Metal-organic framework with his study of Electrocatalyst. His Hydrogen production study which covers Electrolysis of water that intersects with Water splitting and Nanotechnology.
Jun Zhong works mostly in the field of Active site, limiting it down to topics relating to Protonation and, in certain cases, Photochemistry. Jun Zhong studied Photochemistry and Nanorod that intersect with Photocatalysis. His X-ray absorption spectroscopy research incorporates themes from Lewis acids and bases and Reaction mechanism.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Metal-free efficient photocatalyst for stable visible water splitting via a two-electron pathway
Juan Liu;Yang Liu;Naiyun Liu;Yuzhi Han.
Science (2015)
High Efficiency Photocatalytic Water Splitting Using 2D α-Fe2O3/g-C3N4 Z-Scheme Catalysts
Xiaojie She;Jingjie Wu;Hui Xu;Hui Xu;Jun Zhong.
Advanced Energy Materials (2017)
Nitrogen-Doped sp2-Hybridized Carbon as a Superior Catalyst for Selective Oxidation
Yongjun Gao;Gang Hu;Jun Zhong;Zujin Shi.
Angewandte Chemie (2013)
Mo2C Nanoparticles Dispersed on Hierarchical Carbon Microflowers for Efficient Electrocatalytic Hydrogen Evolution
Yang Huang;Qiufang Gong;Xuening Song;Kun Feng.
ACS Nano (2016)
Highly active and durable methanol oxidation electrocatalyst based on the synergy of platinum-nickel hydroxide-graphene.
Wenjing Huang;Hongtao Wang;Jigang Zhou;Jian Wang.
Nature Communications (2015)
Electrochemical CO 2 Reduction with Atomic Iron-Dispersed on Nitrogen-Doped Graphene
Chenhao Zhang;Shize Yang;Jingjie Wu;Mingjie Liu;Mingjie Liu.
Advanced Energy Materials (2018)
Metallic Cobalt Nanoparticles Encapsulated in Nitrogen-Enriched Graphene Shells: Its Bifunctional Electrocatalysis and Application in Zinc–Air Batteries
Min Zeng;Yiling Liu;Feipeng Zhao;Kaiqi Nie.
Advanced Functional Materials (2016)
Over 56.55% Faradaic efficiency of ambient ammonia synthesis enabled by positively shifting the reaction potential.
Mengfan Wang;Sisi Liu;Tao Qian;Jie Liu.
Nature Communications (2019)
Metal Nanoparticle/Carbon Quantum Dot Composite as a Photocatalyst for High-Efficiency Cyclohexane Oxidation
Ruihua Liu;Hui Huang;Haitao Li;Yang Liu.
ACS Catalysis (2014)
Supported Cobalt Polyphthalocyanine for High-Performance Electrocatalytic CO2 Reduction
Na Han;Yu Wang;Lu Ma;Jianguo Wen.
Chem (2017)
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