| 1 |
Ionic liquid assisted solid-state synthesis of lithium iron oxide nanoparticles for rechargeable lithium ion batteries
Krummacher J, Passerini S, Balducci A
Solid State Ionics, 280, 37, 2015 |
| 2 |
Synthesis of high-capacity Ti- and/or Fe-substituted Li2MnO3 positive electrode materials with high initial cycle efficiency by application of the carbothermal reduction method
Tabuchi M, Nabeshima Y, Takeuchi T, Kageyama H, Imaizumi J, Shibuya H, Akimoto J
Journal of Power Sources, 221, 427, 2013 |
| 3 |
Structure and electrode reactions of layered rocksalt LiFeO2 nanoparticles for lithium battery cathode
Hirayama M, Tomita H, Kubota K, Kanno R
Journal of Power Sources, 196(16), 6809, 2011 |
| 4 |
Preparation of alpha-LiFeO2-based cathode materials by an ionic exchange method
Wu SH, Liu HY
Journal of Power Sources, 174(2), 789, 2007 |
| 5 |
Redox behaviour of iron during delithiation in LixCo1-yFeyO2 solid solution: An in situ Fe-57 Mossbauer study
Aldon L, Olivier-Fourcade J, Jumas JC, Holzapfel M, Darie C, Strobel P
Journal of Power Sources, 146(1-2), 259, 2005 |
| 6 |
Synthesis and structural changes of LixFeyOz material prepared by a solid-state method
Lee YT, Yoon CS, Lee YS, Sun YK
Journal of Power Sources, 134(1), 88, 2004 |
| 7 |
A novel modified NiO cathode for molten carbonate fuel cells
Li F, Chen HY, Wang CM, Hu KA
Journal of Electroanalytical Chemistry, 531(1), 53, 2002 |
| 8 |
Lithium-ion conductors of the system LiCo1-xFexO2: a first electrochemical investigation
Holzapfel M, Schreiner R, Ott A
Electrochimica Acta, 46(7), 1063, 2001 |
| 9 |
The reduction of the irreversible capacity of metal oxide-based negative electrodes for Li-ion batteries
Prosini PP, Carewska M, Cardellini F, Passerini S
Molecular Crystals and Liquid Crystals Science and Technology. Section A. Molecular Crystals and Liquid Crystals, 340, 437, 2000 |
