The scientist’s investigation covers issues in Chemical engineering, Nanotechnology, Lithium, Cartilage and Nuclear magnetic resonance. His Chemical engineering research incorporates elements of Pseudocapacitance, Electrochemistry, Anode and Sulfur. His studies deal with areas such as Ion, Porosity and Carbon as well as Nanotechnology.
His Lithium research is multidisciplinary, incorporating perspectives in Mesoporous material and Calcination. His work deals with themes such as Anisotropy and Microscopy, which intersect with Cartilage. His work on Magic angle and Relaxation as part of general Nuclear magnetic resonance study is frequently linked to Phase and Collagenase, therefore connecting diverse disciplines of science.
His primary areas of study are Chemical engineering, Cartilage, Lithium, Electrochemistry and Anode. His research investigates the connection with Chemical engineering and areas like Sulfur which intersect with concerns in Inorganic chemistry. His research in Cartilage intersects with topics in Resolution, Nuclear magnetic resonance and Biomedical engineering.
Within one scientific family, he focuses on topics pertaining to Anisotropy under Nuclear magnetic resonance, and may sometimes address concerns connected to Polarized light microscopy. His study in Electrochemistry is interdisciplinary in nature, drawing from both Composite number, Porosity and Nanotechnology. His studies in Anode integrate themes in fields like Composite material and Electrolysis.
Chemical engineering, Lithium, Electrochemistry, Raw material and Anode are his primary areas of study. His Chemical engineering research includes themes of Electrolyte, Carbon, Metal and Porosity. His Porosity research incorporates themes from Composite number and Adsorption.
His work carried out in the field of Lithium brings together such families of science as Inorganic chemistry, Lithium fluoride, Potassium amide and Potassium. In his work, Chemical substance is strongly intertwined with Nanotechnology, which is a subfield of Electrochemistry. Yang Xia merges many fields, such as Anode and Cathode, in his writings.
His primary scientific interests are in Chemical engineering, Anode, Lithium, Electrochemistry and Thin film. The various areas that Yang Xia examines in his Chemical engineering study include Carbon, Catalysis, Synthesis methods and Lithium sulfur. His research in Anode intersects with topics in Electrolyte and Engineering physics.
His studies in Lithium integrate themes in fields like Nanoparticle, Nanocomposite and Graphite. The Electrochemistry study combines topics in areas such as Low voltage, Yield, Nanotechnology and Etching. In general Nanotechnology study, his work on MXenes often relates to the realm of Science, technology and society, thereby connecting several areas of interest.
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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)
Green and Facile Fabrication of Hollow Porous MnO/C Microspheres from Microalgaes for Lithium-Ion Batteries
Yang Xia;Zhen Xiao;Zhen Xiao;Xiao Dou;Hui Huang.
ACS Nano (2013)
3D lithium metal embedded within lithiophilic porous matrix for stable lithium metal batteries
Chengbin Jin;Ouwei Sheng;Jianmin Luo;Huadong Yuan.
Nano Energy (2017)
NMR microscopy of dynamic displacements: k-space and q-space imaging
P T Callaghan;C D Eccles;Y Xia.
Journal of Physics E: Scientific Instruments (1988)
Popcorn Inspired Porous Macrocellular Carbon: Rapid Puffing Fabrication from Rice and Its Applications in Lithium–Sulfur Batteries
Yu Zhong;Xinhui Xia;Shengjue Deng;Jiye Zhan.
Advanced Energy Materials (2018)
Magic-angle effect in magnetic resonance imaging of articular cartilage: a review.
Investigative Radiology (2000)
Quantitative in situ correlation between microscopic MRI and polarized light microscopy studies of articular cartilage
Y. Xia;J.B. Moody;N. Burton-Wurster;G. Lust.
Osteoarthritis and Cartilage (2001)
Confining Sulfur in Integrated Composite Scaffold with Highly Porous Carbon Fibers/Vanadium Nitride Arrays for High-Performance Lithium–Sulfur Batteries
Yu Zhong;Dongliang Chao;Shengjue Deng;Jiye Zhan.
Advanced Functional Materials (2018)
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