Jing Chen
5 Papers
Jing Chen is an academic researcher. The author has contributed to research in topics: Chemistry & Ion. The author has an hindex of 2, co-authored 3 publications.
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Papers
Simultaneous cation-anion regulation of sodium vanadium phosphate cathode materials for high-energy and cycle-stable sodium-ion batteries
Mingyue Dou,Yuxiang Zhang,Jing Wang,Xiangyi Zheng,Jing Chen,Bo Han,Kaisheng Xia,Qiang Gao,Xiaoxiao Liu,Cheng Guang Zhu,Ruimin Sun,Zhao Cai +11 more
TL;DR: In this article , a simultaneous cation-anion regulation strategy is put forward to design high-capacity and cycle-stable NVP cathode materials, and anionic silicate is introduced to substitute the phosphate and improve Na+-storage capacity, meanwhile, cationic K+ is introduced as pillar ions to stabilize the crystal structure and enhance the reversibility of the nVP cathodes.
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Substituting inert phosphate with redox-active silicate towards advanced polyanion-type cathode materials for sodium-ion batteries.
Ruimin Sun,Mingyue Dou,Yuxiang Zhang,Jing Chen,Yuhao Chen,Bo Han,Kaisheng Xia,Qiang Gao,Xiaoxiao Liu,Zhao Cai,Cheng Guang Zhu +10 more
TL;DR: In this article , the authors proposed substituting an inert phosphate with a redox-active silicate to improve the energy density and intrinsic electroconductivity of polyanion-type phosphate materials, thus enabling an advance in sodium-ion battery cathodes.
18
Glassy State Hydroxide Materials for Oxygen Evolution Electrocatalysis.
Jing Wang,Jing Chen,Jian Zhang,Bo Han,Ruimin Sun,Chenggang Zhou,Zhao Cai +6 more
TL;DR: Glassy state hydroxide materials exhibit high intrinsic activity for oxygen evolution catalysis due to their unique disordered structure and optimized oxygen intermediates adsorption.
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Boric acid templating synthesis of highly-dense yet ultramicroporous carbons for compact capacitive energy storage
Haoran Chen,Yudie Li,Xin Li,Xue Gao,Jing Chen,Bo Han,Qiang Gao,Renzong Hu,Chenggang Zhou,Kaisheng Xia,Min Zhu +10 more
TL;DR: Researchers develop a scalable boric acid templating technique to create highly-dense, ultramicroporous carbons with exceptional compact capacitive energy storage, achieving a record-breaking volumetric energy density of 32.6 Wh L-1 in an aqueous supercapacitor.
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