1 |
New insights into pre-lithiation kinetics of graphite anodes via nuclear magnetic resonance spectroscopy Holtstiege F, Schmuch R, Winter M, Brunklaus G, Placke T Journal of Power Sources, 378, 522, 2018 |
2 |
A novel mechanistic modeling framework for analysis of electrode balancing and degradation modes in commercial lithium-ion cells Schindler S, Danzer MA Journal of Power Sources, 343, 226, 2017 |
3 |
Where is the lithium? Quantitative determination of the lithium distribution in lithium ion battery cells: Investigations on the influence of the temperature, the C-rate and the cell type Vortmann-Westhoven B, Winter M, Nowak S Journal of Power Sources, 346, 63, 2017 |
4 |
Lithium loss in the solid electrolyte interphase: Lithium quantification of aged lithium ion battery graphite electrodes by means of laser ablation inductively coupled plasma mass spectrometry and inductively coupled plasma optical emission spectroscopy Schwieters T, Evertz M, Mense M, Winter M, Nowak S Journal of Power Sources, 356, 47, 2017 |
5 |
Evidence of loss of active lithium in titanium-doped LiNi0.5Mn1.5O4/graphite cells Howeling A, Glatthaar S, Notzel D, Binder JR Journal of Power Sources, 274, 1267, 2015 |
6 |
Capacity loss induced by lithium deposition at graphite anode for LiFePO4/graphite cell cycling at different temperatures Tan L, Zhang L, Sun QN, Shen M, Qu QT, Zheng HH Electrochimica Acta, 111, 802, 2013 |
7 |
Lithium loss mechanisms during synthesis of layered LixNi2-xO2 for lithium ion batteries McCalla E, Carey GH, Dahn JR Solid State Ionics, 219, 11, 2012 |