Advances and issues in developing salt-concentrated battery electrolytes Y Yamada, J Wang, S Ko, E Watanabe, A Yamada Nature Energy 4 (4), 269-280, 2019 | 1330 | 2019 |
Hydrate-melt electrolytes for high-energy-density aqueous batteries Y Yamada, K Usui, K Sodeyama, S Ko, Y Tateyama, A Yamada Nature Energy 1 (10), 1-9, 2016 | 860 | 2016 |
A cyclic phosphate-based battery electrolyte for high voltage and safe operation Q Zheng, Y Yamada, R Shang, S Ko, YY Lee, K Kim, E Nakamura, ... Nature Energy 5 (4), 291-298, 2020 | 341 | 2020 |
Lithium-salt monohydrate melt: A stable electrolyte for aqueous lithium-ion batteries S Ko, Y Yamada, K Miyazaki, T Shimada, E Watanabe, Y Tateyama, ... Electrochemistry Communications 104, 106488, 2019 | 159 | 2019 |
Electrode potential influences the reversibility of lithium-metal anodes S Ko, T Obukata, T Shimada, N Takenaka, M Nakayama, A Yamada, ... Nature Energy 7 (12), 1217-1224, 2022 | 123 | 2022 |
Sodium‐and Potassium‐Hydrate Melts Containing Asymmetric Imide Anions for High‐Voltage Aqueous Batteries Q Zheng, S Miura, K Miyazaki, S Ko, E Watanabe, M Okoshi, CP Chou, ... Angewandte Chemie 131 (40), 14340-14345, 2019 | 105 | 2019 |
Concentrated electrolytes widen the operating temperature range of lithium‐ion batteries J Wang, Q Zheng, M Fang, S Ko, Y Yamada, A Yamada Advanced Science 8 (18), 2101646, 2021 | 92 | 2021 |
An overlooked issue for high-voltage Li-ion batteries: Suppressing the intercalation of anions into conductive carbon S Ko, Y Yamada, A Yamada Joule 5 (4), 998-1009, 2021 | 63 | 2021 |
Designing positive electrodes with high energy density for lithium-ion batteries M Okubo, S Ko, D Dwibedi, A Yamada Journal of Materials Chemistry A 9 (12), 7407-7421, 2021 | 52 | 2021 |
A 62 m K-ion aqueous electrolyte S Ko, Y Yamada, A Yamada Electrochemistry Communications 116, 106764, 2020 | 49 | 2020 |
Dense charge accumulation in MXene with a hydrate-melt electrolyte K Kim, Y Ando, A Sugahara, S Ko, Y Yamada, M Otani, M Okubo, ... Chemistry of Materials 31 (14), 5190-5196, 2019 | 47 | 2019 |
Anhydrous Fast Proton Transport Boosted by the Hydrogen Bond Network in a Dense Oxide‐Ion Array of α‐MoO3 Z Ma, XM Shi, S Nishimura, S Ko, M Okubo, A Yamada Advanced Materials 34 (34), 2203335, 2022 | 45 | 2022 |
Formation of a solid electrolyte interphase in hydrate-melt electrolytes S Ko, Y Yamada, A Yamada ACS applied materials & interfaces 11 (49), 45554-45560, 2019 | 43 | 2019 |
Electrolyte design for lithium-ion batteries with a cobalt-free cathode and silicon oxide anode S Ko, X Han, T Shimada, N Takenaka, Y Yamada, A Yamada Nature Sustainability 6 (12), 1705-1714, 2023 | 41 | 2023 |
A 4.8 V Reversible Li2CoPO4F/Graphite Battery Enabled by Concentrated Electrolytes and Optimized Cell Design S Ko, Y Yamada, A Yamada Batteries & Supercaps 3 (9), 910-916, 2020 | 27 | 2020 |
Peroxidase-modified cup-stacked carbon nanofiber networks for electrochemical biosensing with adjustable dynamic range S Ko, Y Takahashi, H Fujita, T Tatsuma, A Sakoda, K Komori RSC advances 2 (4), 1444-1449, 2012 | 27 | 2012 |
Publisher Correction: Advances and issues in developing salt-concentrated battery electrolytes Y Yamada, J Wang, S Ko, E Watanabe, A Yamada Nature Energy 4 (5), 427-427, 2019 | 21 | 2019 |
Controlled direct electron transfer kinetics of fructose dehydrogenase at cup-stacked carbon nanofibers K Komori, J Huang, N Mizushima, S Ko, T Tatsuma, Y Sakai Physical Chemistry Chemical Physics 19 (40), 27795-27800, 2017 | 20 | 2017 |
Electrochemical properties of oxygenated cup-stacked carbon nanofiber-modified electrodes S Ko, T Tatsuma, A Sakoda, Y Sakai, K Komori Physical Chemistry Chemical Physics 16 (24), 12209-12213, 2014 | 19 | 2014 |
Stability of conductive carbon additives in 5 V-class Li-ion batteries S Ko, Y Yamada, L Lander, A Yamada Carbon 158, 766-771, 2020 | 17 | 2020 |