| 1 |
Ambient lithium-air battery enabled by a versatile oxygen electrode based on boron carbide supported ruthenium
Ruan YL, Yu LM, Song SD, Qin XH, Sun J, Li WJ, Chen BT
International Journal of Hydrogen Energy, 44(59), 31153, 2019 |
| 2 |
V2O5-NiO composite nanowires: A novel and highly efficient carbon-free electrode for non-aqueous Li-air batteries operated in ambient air
Zhang RH, Zhao TS, Jiang HR, Wu MC, Zeng L
Journal of Power Sources, 409, 76, 2019 |
| 3 |
alpha-MnO2 nanorods supported on porous graphitic carbon nitride as efficient electrocatalysts for lithium-air batteries
Hang Y, Zhang CF, Luo XM, Xie YS, Xin S, Li YT, Zhang DW, Goodenough JB
Journal of Power Sources, 392, 15, 2018 |
| 4 |
Graphene supported heterogeneous catalysts for Li-O-2 batteries
Alaf M, Tocoglu U, Kartal M, Akbulut H
Applied Surface Science, 380, 185, 2016 |
| 5 |
Composite Nanofibers as Advanced Materials for Li-ion, Li-O-2 and Li-S Batteries
Agubra VA, Zuniga L, Flores D, Villareal J, Alcoutlabi M
Electrochimica Acta, 192, 529, 2016 |
| 6 |
Influence of Ambient Air on Cell Reactions of Li-air Batteries
Huang ST, Cui ZH, Zhao N, Sun JY, Guo XX
Electrochimica Acta, 191, 473, 2016 |
| 7 |
The Role of PTFE in Cathode Transition Layer in Aqueous Electrolyte Li-Air Battery
Li YF, Huang K, MacGregor JD, Xing YC
Electrochimica Acta, 191, 996, 2016 |
| 8 |
Electrochemical characteristic of based on carbon mixed with organic metal complex (Co(mqph)) in alkaline media Li-air battery
Ahn CH, Okada T, Ishida M, Yoo E, Zhou HS
Journal of Power Sources, 307, 474, 2016 |
| 9 |
Free standing flexible graphene oxide plus alpha-MnO2 composite cathodes for Li-Air batteries
Ozcan S, Tokur M, Cetinkaya T, Guler A, Uysal M, Guler MO, Akbulut H
Solid State Ionics, 286, 34, 2016 |
| 10 |
Density Functional Theory (DFT) Study for Role of Ion-Conducting Lithium Salts Regarding the Oxygen Reduction Reaction (ORR) Kinetics in Li-air (O-2) Batteries
Bhatt MD, Lee JS
Electrochimica Acta, 182, 1124, 2015 |
