Anode, Lithium, Inorganic chemistry, Nanotechnology and Sulfur are his primary areas of study. His research in Anode intersects with topics in Electrolyte, Metallurgy and Electrochemistry, Overpotential. The Lithium study combines topics in areas such as Cobalt, Tin, Metal, Tin oxide and Nitride.
His studies examine the connections between Inorganic chemistry and genetics, as well as such issues in Nanoparticle, with regards to Decomposition. His Nanotechnology study integrates concerns from other disciplines, such as Ion, Carbide, Carbon and Catalysis. His Sulfur study incorporates themes from Lithium–sulfur battery, Faraday efficiency and Covalent bond.
His primary areas of investigation include Lithium, Electrochemistry, Anode, Cathode and Nanotechnology. His Lithium research is multidisciplinary, incorporating elements of Carbon, Metal and Catalysis. His Electrochemistry research also works with subjects such as
His work carried out in the field of Anode brings together such families of science as Nanocomposite, Amorphous solid, Nanoparticle, Ion and Supercritical fluid. His specific area of interest is Nanotechnology, where Chu Liang studies Graphene. His Sulfur research focuses on Inorganic chemistry and how it connects with Imide and Hydrogen.
Chu Liang focuses on Lithium, Electrochemistry, Anode, Carbon and Porosity. Chu Liang combines subjects such as Scientific method, Carbon dioxide, Catalysis and Amorphous carbon with his study of Lithium. Chu Liang has included themes like Electrolyte, Nanotechnology, Chemical substance and Particle size in his Electrochemistry study.
The various areas that Chu Liang examines in his Nanotechnology study include Surface modification and Band gap. His Anode research includes themes of Ion, Nanoparticle and Nanocomposite. His studies in Porosity integrate themes in fields like Mercury, Adsorption, Environmental chemistry, Composite number and Supercritical fluid.
Chu Liang mainly focuses on Anode, Thin film, Electrochemistry, Electrochromism and Optoelectronics. In general Anode study, his work on Faraday efficiency often relates to the realm of Engineering physics, thereby connecting several areas of interest. The subject of his Faraday efficiency research is within the realm of Lithium.
His Electrochemistry research incorporates themes from Nanotechnology, MXenes, Chemical substance and Surface modification. His Electrochromism study combines topics in areas such as Supercapacitor, Capacitance, Solar cell and Electrical conductor. His Electrolyte research integrates issues from Lithium battery and Ceramic.
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.
Strong Sulfur Binding with Conducting Magnéli-Phase TinO2n–1 Nanomaterials for Improving Lithium–Sulfur Batteries
Xinyong Tao;Jianguo Wang;Zhuogao Ying;Qiuxia Cai.
Nano Letters (2014)
Pillared Structure Design of MXene with Ultralarge Interlayer Spacing for High-Performance Lithium-Ion Capacitors.
Jianmin Luo;Wenkui Zhang;Huadong Yuan;Chengbin Jin.
ACS Nano (2017)
Sn4+ Ion Decorated Highly Conductive Ti3C2 MXene: Promising Lithium-Ion Anodes with Enhanced Volumetric Capacity and Cyclic Performance
Jianmin Luo;Xinyong Tao;Jun Zhang;Yang Xia.
ACS Nano (2016)
Catalytic synthesis and photoluminescence of β-Ga2O3 nanowires
C. H. Liang;G. W. Meng;G. Z. Wang;Y. W. Wang.
Applied Physics Letters (2001)
3D lithium metal embedded within lithiophilic porous matrix for stable lithium metal batteries
Chengbin Jin;Ouwei Sheng;Jianmin Luo;Huadong Yuan.
Nano Energy (2017)
Lithium alloys and metal oxides as high-capacity anode materials for lithium-ion batteries
Chu Liang;Mingxia Gao;Hongge Pan;Yongfeng Liu.
Journal of Alloys and Compounds (2013)
Amorphous Fe2O3 as a high-capacity, high-rate and long-life anode material for lithium ion batteries
Yinzhu Jiang;Dan Zhang;Yong Li;Tianzhi Yuan.
Nano Energy (2014)
A facile synthesis of Fe3O4/C composite with high cycle stability as anode material for lithium-ion batteries
Peng Wang;Mingxia Gao;Hongge Pan;Jialei Zhang.
Journal of Power Sources (2013)
Facilitation of sulfur evolution reaction by pyridinic nitrogen doped carbon nanoflakes for highly-stable lithium-sulfur batteries
Huadong Yuan;Wenkui Zhang;Jian-guo Wang;Guangmin Zhou.
Energy Storage Materials (2018)
Efficient Activation of Li2S by Transition Metal Phosphides Nanoparticles for Highly Stable Lithium–Sulfur Batteries
Huadong Yuan;Xianlang Chen;Guangmin Zhou;Wenkui Zhang.
ACS energy letters (2017)
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