| A lithium superionic conductor N Kamaya, K Homma, Y Yamakawa, M Hirayama, R Kanno, M Yonemura, ... Nature materials 10 (9), 682-686, 2011 | 4518 | 2011 |
| High-power all-solid-state batteries using sulfide superionic conductors Y Kato, S Hori, T Saito, K Suzuki, M Hirayama, A Mitsui, M Yonemura, ... Nature Energy 1 (4), 1-7, 2016 | 2816 | 2016 |
| All-solid-state batteries with thick electrode configurations Y Kato, S Shiotani, K Morita, K Suzuki, M Hirayama, R Kanno The journal of physical chemistry letters 9 (3), 607-613, 2018 | 196 | 2018 |
| Discharge performance of all-solid-state battery using a lithium superionic conductor Li10GeP2S12 Y Kato, K Kawamoto, R Kanno, M Hirayama Electrochemistry 80 (10), 749-751, 2012 | 170 | 2012 |
| Synthesis, structure, and conduction mechanism of the lithium superionic conductor Li 10+ δ Ge 1+ δ P 2− δ S 12 O Kwon, M Hirayama, K Suzuki, Y Kato, T Saito, M Yonemura, ... Journal of Materials Chemistry A 3 (1), 438-446, 2015 | 167 | 2015 |
| Sulfide solid electrolyte material, battery, and method for producing sulfide solid electrolyte material R Kanno, M Hirayama, K Yuki, K Kawamoto, S Hama, T Otomo, ... US Patent 8,697,292, 2014 | 129 | 2014 |
| Synthesis, structure and lithium ionic conductivity of solid solutions of Li10 (Ge1− xMx) P2S12 (M= Si, Sn) Y Kato, R Saito, M Sakano, A Mitsui, M Hirayama, R Kanno Journal of Power Sources 271, 60-64, 2014 | 124 | 2014 |
| Li10GeP2S12‐Type Superionic Conductors: Synthesis, Structure, and Ionic Transportation Y Kato, S Hori, R Kanno Advanced Energy Materials 10 (42), 2002153, 2020 | 119 | 2020 |
| Superionic diffusion through frustrated energy landscape D Di Stefano, A Miglio, K Robeyns, Y Filinchuk, M Lechartier, A Senyshyn, ... Chem 5 (9), 2450-2460, 2019 | 113 | 2019 |
| Synthesis, structure, and ionic conductivity of solid solution, Li 10+ δ M 1+ δ P 2− δ S 12 (M= Si, Sn) S Hori, K Suzuki, M Hirayama, Y Kato, T Saito, M Yonemura, R Kanno Faraday discussions 176, 83-94, 2014 | 99 | 2014 |
| The influence of void space on ion transport in a composite cathode for all-solid-state batteries D Hlushkou, AE Reising, N Kaiser, S Spannenberger, S Schlabach, ... Journal of Power Sources 396, 363-370, 2018 | 86 | 2018 |
| Preparation of water-soluble carbon nanotubes using a pulsed streamer discharge in water K Imasaka, J Suehiro, Y Kanatake, Y Kato, M Hara Nanotechnology 17 (14), 3421, 2006 | 86 | 2006 |
| Phase Diagram of the Li4GeS4–Li3PS4 Quasi‐Binary System Containing the Superionic Conductor Li10GeP2S12 S Hori, M Kato, K Suzuki, M Hirayama, Y Kato, R Kanno Journal of the American Ceramic Society 98 (10), 3352-3360, 2015 | 77 | 2015 |
| Ion transport limitations in all-solid-state lithium battery electrodes containing a sulfide-based electrolyte N Kaiser, S Spannenberger, M Schmitt, M Cronau, Y Kato, B Roling Journal of Power Sources 396, 175-181, 2018 | 73 | 2018 |
| Lithium Superionic Conductor Li9.42Si1.02P2.1S9.96O2.04 with Li10GeP2S12-Type Structure in the Li2S–P2S5–SiO2 Pseudoternary System … S Hori, K Suzuki, M Hirayama, Y Kato, R Kanno Frontiers in Energy Research 4, 38, 2016 | 71 | 2016 |
| Operando visualization of morphological dynamics in all‐solid‐state batteries X Wu, J Billaud, I Jerjen, F Marone, Y Ishihara, M Adachi, Y Adachi, ... Advanced Energy Materials 9 (34), 1901547, 2019 | 70 | 2019 |
| Weak Anisotropic Lithium-Ion Conductivity in Single Crystals of Li10GeP2S12 R Iwasaki, S Hori, R Kanno, T Yajima, D Hirai, Y Kato, Z Hiroi Chemistry of Materials 31 (10), 3694-3699, 2019 | 70 | 2019 |
| Enhancement of microplasma-based water-solubilization of single-walled carbon nanotubes using gas bubbling in water K Imasaka, Y Kato, J Suehiro Nanotechnology 18 (33), 335602, 2007 | 67 | 2007 |
| Structure–property relationships in lithium superionic conductors having a Li10GeP2S12-type structure S Hori, S Taminato, K Suzuki, M Hirayama, Y Kato, R Kanno Acta Crystallographica Section B: Structural Science, Crystal Engineering …, 2015 | 59 | 2015 |
| Sulfide solid electrolyte material, lithium solid-state battery, and method for producing sulfide solid electrolyte material T Ohtomo, K Kawamoto, S Hama, K Yuki US Patent 9,172,113, 2015 | 54 | 2015 |
