His primary scientific interests are in Hydrogen storage, Hydrogen, Nanotechnology, Inorganic chemistry and Alloy. His research in Hydrogen storage intersects with topics in Dehydrogenation, Chemical stability and Hydride. His Hydrogen research integrates issues from Catalysis and Magnesium.
His research on Nanotechnology frequently connects to adjacent areas such as Anode. His Inorganic chemistry research includes themes of Hydrogen production, Hydrolysis and Lithium. His work carried out in the field of Alloy brings together such families of science as Electrochemistry, Electrode and Activation energy.
Jiangwen Liu focuses on Anode, Hydrogen storage, Hydrogen, Alloy and Composite number. Jiangwen Liu has researched Anode in several fields, including Battery, Nanoparticle, Nanotechnology and Lithium. His study looks at the relationship between Lithium and fields such as Graphite, as well as how they intersect with chemical problems.
Jiangwen Liu has included themes like Solid solution, Laves phase, Dehydrogenation, Desorption and Magnesium in his Hydrogen storage study. His Hydrogen research incorporates elements of Inorganic chemistry, Hydrolysis and Catalysis, Sodium borohydride. His biological study spans a wide range of topics, including Crystallography, Crystallization, Hydride and Phase.
His primary areas of investigation include Hydrogen storage, Anode, Hydrogen, Lithium and Alloy. His Hydrogen storage study combines topics in areas such as Annealing, Microstructure, Enthalpy and Dehydrogenation. As part of the same scientific family, Jiangwen Liu usually focuses on Anode, concentrating on Battery and intersecting with Cathode, Phosphide, Nickel, Electrode and Nanocomposite.
His Hydrogen research includes elements of Inorganic chemistry, Hydrolysis and Sodium borohydride, Catalysis. The Lithium study combines topics in areas such as Composite number, Carbon and Graphene. His studies in Alloy integrate themes in fields like Hydride and Phase.
Jiangwen Liu mainly focuses on Hydrogen, Hydrolysis, Anode, Lithium and Hydrogen production. His Hydrogen research is mostly focused on the topic Hydrogen storage. His work focuses on many connections between Anode and other disciplines, such as Carbon, that overlap with his field of interest in Electrochemistry, Amorphous solid, Graphite, Composite number and Faraday efficiency.
His Lithium study combines topics from a wide range of disciplines, such as Supercapacitor, Oxide and Power density. His research integrates issues of Ball mill, Doping, Hydrogen fuel, Inorganic chemistry and Alloy in his study of Hydrogen production. His Catalysis research is multidisciplinary, incorporating elements of Gravimetric analysis, Fuel cells and Nanotechnology.
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Enhanced Hydrogen Storage Kinetics and Stability by Synergistic Effects of in Situ Formed CeH2.73 and Ni in CeH2.73-MgH2‑Ni Nanocomposites
L. Z. Ouyang;X. S. Yang;M. Zhu;M. Zhu;J. W. Liu.
Journal of Physical Chemistry C (2014)
New Nanoconfined Galvanic Replacement Synthesis of Hollow [email protected] Yolk–Shell Spheres Constituting a Stable Anode for High-Rate Li/Na-Ion Batteries
Jun Liu;Litao Yu;Chao Wu;Yuren Wen.
Nano Letters (2017)
A General Metal-Organic Framework (MOF)-Derived Selenidation Strategy for In Situ Carbon-Encapsulated Metal Selenides as High-Rate Anodes for Na-Ion Batteries
Xijun Xu;Jun Liu;Jiangwen Liu;Liuzhang Ouyang.
Advanced Functional Materials (2018)
Structure and conductivity of multi-walled carbon nanotube/poly(3-hexylthiophene) composite films
Anthony W. Musumeci;Glaura G. Silva;Jiang-Wen Liu;Wayde N. Martens.
Enhancing the Regeneration Process of Consumed NaBH4 for Hydrogen Storage
Liuzhang Ouyang;Wei Chen;Jiangwen Liu;Michael Felderhoff.
Advanced Energy Materials (2017)
Mg–TM (TM: Ti, Nb, V, Co, Mo or Ni) core–shell like nanostructures: synthesis, hydrogen storage performance and catalytic mechanism
Jie Cui;Jie Cui;Jiangwen Liu;Hui Wang;Liuzhang Ouyang.
Journal of Materials Chemistry (2014)
Remarkable enhancement in dehydrogenation of MgH2 by a nano-coating of multi-valence Ti-based catalysts
Jie Cui;Jie Cui;Hui Wang;Jiangwen Liu;Liuzhang Ouyang.
Journal of Materials Chemistry (2013)
Robust Pitaya-Structured Pyrite as High Energy Density Cathode for High-Rate Lithium Batteries
Xijun Xu;Jun Liu;Zhengbo Liu;Jiadong Shen.
ACS Nano (2017)
Enhanced dehydriding thermodynamics and kinetics in Mg(In)–MgF2 composite directly synthesized by plasma milling
L.Z. Ouyang;Z.J. Cao;H. Wang;J.W. Liu.
Journal of Alloys and Compounds (2014)
Enhanced high-rate discharge properties of La11.3Mg6.0Sm7.4Ni61.0Co7.2Al7.1 with added graphene synthesized by plasma milling
L.Z. Ouyang;Z.J. Cao;L.L. Li;H. Wang.
International Journal of Hydrogen Energy (2014)
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