His main research concerns Electrocatalyst, Electrochemistry, Reversible hydrogen electrode, Catalysis and Faraday efficiency. His Electrocatalyst research incorporates elements of Doped carbon, S doping, Overpotential and Nanosheet. Other disciplines of study, such as Redox, Yield and Selectivity, are mixed together with his Reversible hydrogen electrode studies.
He interconnects Inorganic chemistry, Dopant and Titanium in the investigation of issues within Yield. His Catalysis study incorporates themes from FOIL method and Oxygen evolution. Within one scientific family, Xifeng Shi focuses on topics pertaining to Electrolysis under Faraday efficiency, and may sometimes address concerns connected to Oxide, Adsorption, Hydrogen storage and Graphene.
Xifeng Shi mainly investigates Electrocatalyst, Electrochemistry, Catalysis, Reversible hydrogen electrode and Faraday efficiency. The various areas that he examines in his Electrocatalyst study include Nanofiber, Nanosheet, Nanotechnology and Oxide. The concepts of his Electrochemistry study are interwoven with issues in Selectivity, Nanoparticle, Adsorption and Carbon.
In his study, which falls under the umbrella issue of Catalysis, Oxygen evolution and Hydrogen production is strongly linked to Overpotential. Xifeng Shi integrates many fields in his works, including Reversible hydrogen electrode, Yield and Inorganic chemistry. Aqueous solution is closely connected to Redox in his research, which is encompassed under the umbrella topic of Faraday efficiency.
His scientific interests lie mostly in Electrocatalyst, Electrochemistry, Nanotechnology, Catalysis and Faraday efficiency. His Electrocatalyst research is multidisciplinary, relying on both Oxide, Nanosheet, Carbon nanofiber, Metal and Nanofiber. His Electrochemistry study combines topics from a wide range of disciplines, such as Combinatorial chemistry, Chemical substance and Adsorption.
His work on Formate as part of general Catalysis research is frequently linked to Homogeneous, bridging the gap between disciplines. His biological study spans a wide range of topics, including Yield and Redox. His Yield research is multidisciplinary, incorporating elements of Selectivity and Graphene.
Electrochemistry, Reversible hydrogen electrode, Faraday efficiency, Electrocatalyst and Density functional theory are his primary areas of study. His Electrochemistry research integrates issues from Nanomaterial-based catalyst and Water splitting. Reversible hydrogen electrode is connected with Catalysis, Yield and Redox in his research.
His study explores the link between Catalysis and topics such as Adsorption that cross with problems in Graphite and Thin film. His Yield research includes elements of Selectivity and Graphene. His work carried out in the field of Electrocatalyst brings together such families of science as Noble metal, Nanofiber, Nanotechnology, Oxygen reduction reaction and Reaction mechanism.
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Electrochemical Ammonia Synthesis via Nitrogen Reduction Reaction on a MoS2 Catalyst: Theoretical and Experimental Studies.
Ling Zhang;Ling Zhang;Xuqiang Ji;Xiang Ren;Yongjun Ma.
Advanced Materials (2018)
Ti3C2Tx (T = F, OH) MXene nanosheets: conductive 2D catalysts for ambient electrohydrogenation of N2 to NH3
Jinxiu Zhao;Lei Zhang;Xiao-Ying Xie;Xianghong Li.
Journal of Materials Chemistry (2018)
Boosted Electrocatalytic N2 Reduction to NH3 by Defect‐Rich MoS2 Nanoflower
Xianghong Li;Xianghong Li;Tingshuai Li;Yongjun Ma;Qin Wei.
Advanced Energy Materials (2018)
Greatly Improving Electrochemical N2 Reduction over TiO2 Nanoparticles by Iron Doping.
Tongwei Wu;Xiaojuan Zhu;Xiaojuan Zhu;Zhe Xing;Shiyong Mou.
Angewandte Chemie (2019)
S-Doped Carbon Nanospheres: An Efficient Electrocatalyst toward Artificial N2 Fixation to NH3
Li Xia;Xiufeng Wu;Yuan Wang;Zhiguo Niu.
Small Methods (2019)
Fabrication of hierarchical CoP [email protected] arrays via space-confined phosphidation toward high-efficiency water oxidation electrocatalysis under alkaline conditions
Xuqiang Ji;Rong Zhang;Xifeng Shi;Abdullah M. Asiri.
Enabling Effective Electrocatalytic N2 Conversion to NH3 by the TiO2 Nanosheets Array under Ambient Conditions
Rong Zhang;Rong Zhang;Xiang Ren;Xifeng Shi;Fengyu Xie.
ACS Applied Materials & Interfaces (2018)
TiO2 nanoparticles–reduced graphene oxide hybrid: an efficient and durable electrocatalyst toward artificial N2 fixation to NH3 under ambient conditions
Xiaoxue Zhang;Xiaoxue Zhang;Qin Liu;Qin Liu;Xifeng Shi;Abdullah M. Asiri.
Journal of Materials Chemistry (2018)
Efficient Electrochemical N2 Reduction to NH3 on MoN Nanosheets Array under Ambient Conditions
Ling Zhang;Ling Zhang;Xuqiang Ji;Xiang Ren;Yonglan Luo.
ACS Sustainable Chemistry & Engineering (2018)
An Fe(TCNQ)2 nanowire array on Fe foil: an efficient non-noble-metal catalyst for the oxygen evolution reaction in alkaline media
Maowen Xie;Maowen Xie;Xiaoli Xiong;Lin Yang;Xifeng Shi.
Chemical Communications (2018)
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