| 1 |
Improving the electrochemical cycling performance of anode materials via facile in situ surface deposition of a solid electrolyte layer
Qi WB, Ben LB, Yu HL, Zhan YJ, Zhao WW, Huang XJ
Journal of Power Sources, 424, 150, 2019 |
| 2 |
Using Li2S to Compensate for the Loss of Active Lithium in Li-ion Batteries
Zhan YJ, Yu HL, Ben LB, Chen YY, Huang XJ
Electrochimica Acta, 255, 212, 2017 |
| 3 |
Nano-Sn embedded in expanded graphite as anode for lithium ion batteries with improved low temperature electrochemical performance
Yan Y, Ben LB, Zhan YJ, Huang XJ
Electrochimica Acta, 187, 186, 2016 |
| 4 |
Controlled solvothermal synthesis and electrochemical performance of LiCoPO4 submicron single crystals as a cathode material for lithium ion batteries
Wu BR, Xu HL, Mu DB, Shi LL, Jiang B, Gai L, Wang L, Liu Q, Ben LB, Wu F
Journal of Power Sources, 304, 181, 2016 |
| 5 |
Enhanced electrochemical performance of Ti-doped Li1.2Mn0.54Co0.13Ni0.13O2 for lithium-ion batteries
Feng X, Gao YR, Ben LB, Yang ZZ, Wang ZX, Chen LQ
Journal of Power Sources, 317, 74, 2016 |
| 6 |
Atomic insight into electrochemical inactivity of lithium chromate (LiCrO2): Irreversible migration of chromium into lithium layers in surface regions
Lyu YC, Ben LB, Sun Y, Tang DC, Xu KQ, Gu L, Xiao RJ, Li H, Chen LQ, Huang XJ
Journal of Power Sources, 273, 1218, 2015 |
| 7 |
Enhanced electrochemical performance of Si-Cu-Ti thin films by surface covered with Cu3Si nanowires
Xu KQ, He Y, Ben LB, Li H, Huang XJ
Journal of Power Sources, 281, 455, 2015 |
| 8 |
Identifying Li+ ion transport properties of aluminum doped lithium titanium phosphate solid electrolyte at wide temperature range
Wang SF, Ben LB, Li H, Chen LQ
Solid State Ionics, 268, 110, 2014 |
| 9 |
The Influence of A-Site Rare Earth Ion Size in Controlling the Curie Temperature of Ba1-xRExTi1-x/4O3
Freeman CL, Dawson JA, Harding JH, Ben LB, Sinclair DC
Advanced Functional Materials, 23(4), 491, 2013 |
