Education Background Ph.D.(2014.9-2021.6), Materials Science, Harbin Institute of Technology B.E.(2009.09-2013.6), chemistry, Harbin Normal University Working Experience 2021.8-now, Lecturer of Battery Technology Research Institute, Jiangsu University |
1. Preparation and electrochemical properties of 3D nanoporous Sb,Ge-based Na-ion battery anodes 2. Study on electrochemical failure mechanism of electrode materials for secondary batteries 3. Preparation and electrochemical properties of self-healing Ga-based Mg-ion battery anode |
1. M.N. Li, et al. Polyaniline-Coated Nanoporous Antimony with Improved Performance for Sodium-ion Battery Anodes[J]. Journal of alloys and compounds, 2021, 861: 158647. (SCI) 2. M.N. Li, et al. Impact of Hierarchical Nanoporous Morphology on the Performance of Alloy-based Sodium-ion Battery Anodes[J]. ACS Applied Energy Materials, 2020, 3: 11231-11241. (SCI) 3. M.N. Li, et al. In Situ Electrochemical Dilatometry Study of (De)lithiation and Polysulfide Dissolution-Induced Dimensional Changes in Lithium-Sulfur Cathodes during Charging and Discharging[J]. Journal of The Electrochemical Society, 2020, 167: 050505. (SCI) 4. M.N. Li, et al. In situ Electrochemical Dilatometry Study of Capacity Fading in Nanoporous Ge-based Na-ion Battery Anodes[J]. Scripta Materialia, 2019, 164: 52-56. (SCI) 5. O. Ruiz, M. Cochrane, M.N. Li, et al. Enhanced Cycling Stability of Macroporous Bulk Antimony-Based Sodium-Ion Battery Anodes Enabled through Active/Inactive Composites[J]. Advanced Energy Materials, 2018, 8: 1801781. (SCI) 6. L. Wang, S. Welborn. H. Kumar. M.N.Li, et al. High-Rate and Long Cycle-Life Alloy-Type Magnesium-Ion Battery Anode Enabled Through (De) magnesiation-Induced Near-Room-Temperature Solid-Liquid Phase Transformation[J]. Advanced Energy Materials, 2019, 9: 1902086. (SCI) |
