| Negating interfacial impedance in garnet-based solid-state Li metal batteries X Han, Y Gong, K Fu, X He, GT Hitz, J Dai, A Pearse, B Liu, H Wang, ... Nature materials 16 (5), 572-579, 2017 | 1769 | 2017 |
| Origin of outstanding stability in the lithium solid electrolyte materials: insights from thermodynamic analyses based on first-principles calculations Y Zhu, X He, Y Mo ACS applied materials & interfaces 7 (42), 23685-23693, 2015 | 1506 | 2015 |
| Electrochemical Stability of Li10GeP2S12 and Li7La3Zr2O12 Solid Electrolytes F Han, Y Zhu, X He, Y Mo, C Wang Advanced Energy Materials 6 (8), 1501590, 2016 | 949 | 2016 |
| First principles study on electrochemical and chemical stability of solid electrolyte–electrode interfaces in all-solid-state Li-ion batteries Y Zhu, X He, Y Mo Journal of Materials Chemistry A 4 (9), 3253-3266, 2016 | 857 | 2016 |
| Origin of fast ion diffusion in super-ionic conductors X He, Y Zhu, Y Mo Nature communications 8 (1), 15893, 2017 | 740 | 2017 |
| Super‐aligned carbon nanotube films as current collectors for lightweight and flexible lithium ion batteries K Wang, S Luo, Y Wu, X He, F Zhao, J Wang, K Jiang, S Fan Advanced Functional Materials 23 (7), 846-853, 2013 | 324 | 2013 |
| Computation-accelerated design of materials and interfaces for all-solid-state lithium-ion batteries AM Nolan, Y Zhu, X He, Q Bai, Y Mo Joule 2 (10), 2016-2046, 2018 | 289 | 2018 |
| Statistical variances of diffusional properties from ab initio molecular dynamics simulations X He, Y Zhu, A Epstein, Y Mo npj Computational Materials 4 (1), 18, 2018 | 284 | 2018 |
| Strategies based on nitride materials chemistry to stabilize Li metal anode Y Zhu, X He, Y Mo Advanced Science 4 (8), 1600517, 2017 | 223 | 2017 |
| Unsupervised discovery of solid-state lithium ion conductors Y Zhang, X He, Z Chen, Q Bai, AM Nolan, CA Roberts, D Banerjee, ... Nature communications 10 (1), 5260, 2019 | 192 | 2019 |
| Crystal structural framework of lithium super‐ionic conductors X He, Q Bai, Y Liu, AM Nolan, C Ling, Y Mo Advanced Energy Materials 9 (43), 1902078, 2019 | 129 | 2019 |
| Accelerated materials design of Na 0.5 Bi 0.5 TiO 3 oxygen ionic conductors based on first principles calculations X He, Y Mo Physical Chemistry Chemical Physics 17 (27), 18035-18044, 2015 | 124 | 2015 |
| Hybrid super-aligned carbon nanotube/carbon black conductive networks: A strategy to improve both electrical conductivity and capacity for lithium ion batteries K Wang, Y Wu, S Luo, X He, J Wang, K Jiang, S Fan Journal of Power Sources 233, 209-215, 2013 | 79 | 2013 |
| Enhanced rate capabilities of Co 3 O 4/carbon nanotube anodes for lithium ion battery applications X He, Y Wu, F Zhao, J Wang, K Jiang, S Fan Journal of Materials Chemistry A 1 (37), 11121-11125, 2013 | 54 | 2013 |
| Computation‐Guided Design of LiTaSiO5, a New Lithium Ionic Conductor with Sphene Structure S Xiong#, X He#, A Han, Z Liu, Z Ren, B McElhenny, AM Nolan, S Chen, ... Advanced Energy Materials 9 (22), 1803821, 2019 | 41 | 2019 |
| First-Principles Study of Oxyhydride H– Ion Conductors: Toward Facile Anion Conduction in Oxide-Based Materials Q Bai, X He, Y Zhu, Y Mo ACS Applied Energy Materials 1 (4), 1626-1634, 2018 | 35 | 2018 |
| Anodes of lithium battery XF He, Y Wu, JP Wang, KL Jiang, SS Fan US Patent App. 13/869,946, 2014 | 25 | 2014 |
| First principles hybrid functional study of small polarons in doped SrCeO3 perovskite: towards computation design of materials with tailored polaron Q Bai, Y Zhu, X He, E Wachsman, Y Mo Ionics 24, 1139-1151, 2018 | 14 | 2018 |
| Li15P4S16Cl3, a Lithium Chlorothiophosphate as a Solid-State Ionic Conductor Z Liu, T Zinkevich, S Indris, X He, J Liu, W Xu, J Bai, S Xiong, Y Mo, ... Inorganic Chemistry 59 (1), 226-234, 2019 | 10 | 2019 |
| Methods for fabricating anodes of lithium battery Y Wu, XF He, JP Wang, KL Jiang, SS Fan US Patent App. 13/869,939, 2014 | 6 | 2014 |
Yifei MoProfessor of Materials Science and Engineering, University of Maryland, College ParkVerified email at umd.edu
