| Lithium batteries and cathode materials MS Whittingham Chemical reviews 104 (10), 4271-4302, 2004 | 7462 | 2004 |
| Pathways for practical high-energy long-cycling lithium metal batteries J Liu, Z Bao, Y Cui, EJ Dufek, JB Goodenough, P Khalifah, Q Li, BY Liaw, ... Nature Energy 4 (3), 180-186, 2019 | 2421 | 2019 |
| Electrical energy storage and intercalation chemistry MS Whittingham Science 192 (4244), 1126-1127, 1976 | 2404 | 1976 |
| Chemistry of intercalation compounds: Metal guests in chalcogenide hosts MS Whittingham Progress in Solid State Chemistry 12 (1), 41-99, 1978 | 1782 | 1978 |
| History, evolution, and future status of energy storage MS Whittingham Proceedings of the IEEE 100 (Special Centennial Issue), 1518-1534, 2012 | 1133 | 2012 |
| Ultimate limits to intercalation reactions for lithium batteries MS Whittingham Chemical reviews 114 (23), 11414-11443, 2014 | 1114 | 2014 |
| Layered vanadium and molybdenum oxides: batteries and electrochromics NA Chernova, M Roppolo, AC Dillon, MS Whittingham Journal of Materials Chemistry 19 (17), 2526-2552, 2009 | 1009 | 2009 |
| Lithium–oxygen batteries: bridging mechanistic understanding and battery performance YC Lu, BM Gallant, DG Kwabi, JR Harding, RR Mitchell, MS Whittingham, ... Energy & Environmental Science 6 (3), 750-768, 2013 | 964 | 2013 |
| Intercalation chemistry SM Whittingha Elsevier, 2012 | 945 | 2012 |
| The role of ternary phases in cathode reactions MS Whittingham Journal of The Electrochemical Society 123 (3), 315, 1976 | 937 | 1976 |
| Hydrothermal synthesis of lithium iron phosphate cathodes S Yang, PY Zavalij, MS Whittingham Electrochemistry Communications 3 (9), 505-508, 2001 | 898 | 2001 |
| Materials challenges facing electrical energy storage MS Whittingham Mrs Bulletin 33 (4), 411-419, 2008 | 834 | 2008 |
| Understanding and applying coulombic efficiency in lithium metal batteries J Xiao, Q Li, Y Bi, M Cai, B Dunn, T Glossmann, J Liu, T Osaka, R Sugiura, ... Nature energy 5 (8), 561-568, 2020 | 656 | 2020 |
| Conversion reaction mechanisms in lithium ion batteries: study of the binary metal fluoride electrodes F Wang, R Robert, NA Chernova, N Pereira, F Omenya, F Badway, X Hua, ... Journal of the American Chemical Society 133 (46), 18828-18836, 2011 | 618 | 2011 |
| Reactivity, stability and electrochemical behavior of lithium iron phosphates S Yang, Y Song, PY Zavalij, MS Whittingham Electrochemistry communications 4 (3), 239-244, 2002 | 576 | 2002 |
| Narrowing the gap between theoretical and practical capacities in Li‐ion layered oxide cathode materials MD Radin, S Hy, M Sina, C Fang, H Liu, J Vinckeviciute, M Zhang, ... Advanced Energy Materials 7 (20), 1602888, 2017 | 571 | 2017 |
| High-energy lithium metal pouch cells with limited anode swelling and long stable cycles C Niu, H Lee, S Chen, Q Li, J Du, W Xu, JG Zhang, MS Whittingham, ... Nature Energy 4 (7), 551-559, 2019 | 563 | 2019 |
| High‐Performance LiNi0.5Mn1.5O4 Spinel Controlled by Mn3+ Concentration and Site Disorder J Xiao, X Chen, PV Sushko, ML Sushko, L Kovarik, J Feng, Z Deng, ... Advanced materials 24 (16), 2109-2116, 2012 | 537 | 2012 |
| Hydrothermal synthesis of lithium iron phosphate J Chen, MS Whittingham Electrochemistry Communications 8 (5), 855-858, 2006 | 462 | 2006 |
| Measurement of sodium ion transport in beta alumina using reversible solid electrodes MS Whittingham, RA Huggins The Journal of Chemical Physics 54 (1), 414-416, 1971 | 449 | 1971 |
Peter ZavalijDirector of X-ray Crystallographic Center, Department of Chemistry and BiochemistryVerified email at umd.edu
