Nonaqueous liquid electrolytes for lithium-based rechargeable batteries K Xu Chemical reviews 104 (10), 4303-4418, 2004 | 6763 | 2004 |
Electrolytes and interphases in Li-ion batteries and beyond K Xu Chemical reviews 114 (23), 11503-11618, 2014 | 3793 | 2014 |
“Water-in-salt” electrolyte enables high-voltage aqueous lithium-ion chemistries L Suo, O Borodin, T Gao, M Olguin, J Ho, X Fan, C Luo, C Wang, K Xu Science 350 (6263), 938-943, 2015 | 2335 | 2015 |
Highly reversible zinc metal anode for aqueous batteries F Wang, O Borodin, T Gao, X Fan, W Sun, F Han, A Faraone, JA Dura, ... Nature materials 17 (6), 543-549, 2018 | 1533 | 2018 |
Before Li ion batteries M Winter, B Barnett, K Xu Chemical reviews 118 (23), 11433-11456, 2018 | 1317 | 2018 |
Electrochemical impedance study on the low temperature of Li-ion batteries SS Zhang, K Xu, TR Jow Electrochimica acta 49 (7), 1057-1061, 2004 | 850 | 2004 |
Non-flammable electrolyte enables Li-metal batteries with aggressive cathode chemistries X Fan, L Chen, O Borodin, X Ji, J Chen, S Hou, T Deng, J Zheng, C Yang, ... Nature nanotechnology 13 (8), 715-722, 2018 | 815 | 2018 |
Quantifying inactive lithium in lithium metal batteries C Fang, J Li, M Zhang, Y Zhang, F Yang, JZ Lee, MH Lee, J Alvarado, ... Nature 572 (7770), 511-515, 2019 | 683 | 2019 |
EIS study on the formation of solid electrolyte interface in Li-ion battery SS Zhang, K Xu, TR Jow Electrochimica acta 51 (8-9), 1636-1640, 2006 | 642 | 2006 |
Electrospun Sb/C fibers for a stable and fast sodium-ion battery anode Y Zhu, X Han, Y Xu, Y Liu, S Zheng, K Xu, L Hu, C Wang ACS nano 7 (7), 6378-6386, 2013 | 628 | 2013 |
The low temperature performance of Li-ion batteries SS Zhang, K Xu, TR Jow Journal of Power Sources 115 (1), 137-140, 2003 | 602 | 2003 |
Advanced High‐Voltage Aqueous Lithium‐Ion Battery Enabled by “Water‐in‐Bisalt” Electrolyte L Suo, O Borodin, W Sun, X Fan, C Yang, F Wang, T Gao, Z Ma, ... Angewandte Chemie International Edition 55 (25), 7136-7141, 2016 | 594 | 2016 |
Highly fluorinated interphases enable high-voltage Li-metal batteries X Fan, L Chen, X Ji, T Deng, S Hou, J Chen, J Zheng, F Wang, J Jiang, ... Chem 4 (1), 174-185, 2018 | 582 | 2018 |
LiBOB as salt for lithium-ion batteries: a possible solution for high temperature operation K Xu, S Zhang, TR Jow, W Xu, CA Angell Electrochemical and Solid-State Letters 5 (1), A26, 2001 | 547 | 2001 |
Aqueous Li-ion battery enabled by halogen conversion–intercalation chemistry in graphite C Yang, J Chen, X Ji, TP Pollard, X Lü, CJ Sun, S Hou, Q Liu, C Liu, ... Nature 569 (7755), 245-250, 2019 | 505 | 2019 |
Localized high-concentration sulfone electrolytes for high-efficiency lithium-metal batteries X Ren, S Chen, H Lee, D Mei, MH Engelhard, SD Burton, W Zhao, ... Chem 4 (8), 1877-1892, 2018 | 484 | 2018 |
“Water‐in‐salt” electrolyte makes aqueous sodium‐ion battery safe, green, and long‐lasting L Suo, O Borodin, Y Wang, X Rong, W Sun, X Fan, S Xu, MA Schroeder, ... Advanced Energy Materials 7 (21), 1701189, 2017 | 461 | 2017 |
Understanding solid electrolyte interface film formation on graphite electrodes S Zhang, MS Ding, K Xu, J Allen, TR Jow Electrochemical and Solid State Letters 4 (12), A206, 2001 | 428 | 2001 |
New concepts in electrolytes M Li, C Wang, Z Chen, K Xu, J Lu Chemical reviews 120 (14), 6783-6819, 2020 | 410 | 2020 |
4.0 V aqueous Li-ion batteries C Yang, J Chen, T Qing, X Fan, W Sun, A von Cresce, MS Ding, ... Joule 1 (1), 122-132, 2017 | 404 | 2017 |