Min Guo
Tongji University
9 Papers
23 Citations
Min Guo is an academic researcher from Tongji University. The author has contributed to research in topics: Electrode & Electrolyte. The author has an hindex of 6, co-authored 8 publications.
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Papers
Three-Dimensional Magnesiophilic Scaffolds for Reduced Passivation toward High-Rate Mg Metal Anodes in a Noncorrosive Electrolyte.
Bingxin Wan,Huanglin Dou,Huanglin Dou,Xiaoli Zhao,Jiahe Wang,Wanyu Zhao,Min Guo,Yijie Zhang,Jinjin Li,Zi-Feng Ma,Xiaowei Yang +10 more
TL;DR: 3D Mg3Bi2 scaffolds for Mg metal are adopted, of which the high surface area reduces the effective current density to avoid the continuous electrolyte decomposition and the good Mg affinity homogenizes the nucleation, which proves the control of dynamic passivation can enable high-power-density MgMetal anodes.
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Three dimensional frameworks of super ionic conductor for thermodynamically and dynamically favorable sodium metal anode
Min Guo,Huanglin Dou,Huanglin Dou,Wanyu Zhao,Xiaoli Zhao,Bingxin Wan,Jiahe Wang,Yuantao Yan,Xiaomin Wang,Zi-Feng Ma,Xiaowei Yang +10 more
TL;DR: In this paper, a super ionic conductor material, Na3V2(PO4)3 (NVP), was introduced as a modulation medium for continuous nucleation, growth and dissolution to suppress Na dendrite.
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Engineering sodium metal anode with sodiophilic bismuthide penetration for dendrite-free and high-rate sodium-ion battery
Wangting Zhao,Min Guo,Zhijun Zuo,Xiaoli Zhao,Huanglin Dou,Yijie Zhang,Shiying Li,Zichen Wu,Yayun Shi,Xiaowei Wang +9 more
TL;DR: In this paper , a hybrid anode with sodiophilic Na3Bi-penetration was developed to develop the abundant phase-boundary ionic transport channels, and the obtained anode was endowed with a high current density (up to 5 mA∙cm−2).
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Decreasing Ion-Diffusion Barrier Enables Superior Na-Ion Storage by Synergizing Hierarchical Architecture and Lattice Distortion.
TL;DR: This work manipulates a bifunctional dopant to prepare micron-sized Na3V2(PO4)3 with extraordinary synergy of hierarchical architecture and lattice distortion and demonstrates that the rational design of morphology and structure compounding lowers the ion diffusion barrier and strengthen the Na+ migration kinetics.
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High-voltage bi-redox lithium-ion capacitor enabled by energizing free water in “water-in-salt” electrolyte
Xiaojun Yan,Xiaojun Yan,Xiaoli Zhao,Congcong Liu,Shengping Wang,Yijie Zhang,Min Guo,Yuanyuan Wang,Liyi Dai,Xiaowei Yang,Xiaowei Yang +10 more
TL;DR: In this paper, the role of free water in the water-in-salt electrolytes as the solvent of high-potential redox-active species, combining with the lithium insertion/deinsertion reaction at the battery-electrode to constitute a bi-redox system for effectively boosting the energy density.
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