Hybrid electrolyte design for high-performance zinc–sulfur battery
Rechargeable aqueous Zn/S batteries exhibit high capacity and energy density. However, the long-term battery performance is bottlenecked by the sulfur side reactions and serious Zn anode dendritic growth in the aqueous electrolyte medium. This work addresses the problem of sulfur side reactions and...
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sg-ntu-dr.10356-1689742023-06-26T01:47:19Z Hybrid electrolyte design for high-performance zinc–sulfur battery Guo, Yuqi Chua, Rodney Chen, Yingqian Cai, Yi Tang, Ernest Jun Jie Lim, Nicholas J. J. Tran, Thu Ha Verma, Vivek Wong, Ming Wah Srinivasan, Madhavi School of Materials Science and Engineering Energy Research Institute @ NTU (ERI@N) Engineering::Materials Aqueous Batteries Conversion Mechanism Rechargeable aqueous Zn/S batteries exhibit high capacity and energy density. However, the long-term battery performance is bottlenecked by the sulfur side reactions and serious Zn anode dendritic growth in the aqueous electrolyte medium. This work addresses the problem of sulfur side reactions and zinc dendrite growth simultaneously by developing a unique hybrid aqueous electrolyte using ethylene glycol as a co-solvent. The designed hybrid electrolyte enables the fabricated Zn/S battery to deliver an unprecedented capacity of 1435 mAh g-1 and an excellent energy density of 730 Wh kg-1 at 0.1 Ag-1 . In addition, the battery exhibits capacity retention of 70% after 250 cycles even at 3 Ag-1 . Moreover, the cathode charge-discharge mechanism studies demonstrate a multi-step conversion reaction. During discharge, the elemental sulfur is sequentially reduced by Zn to S2- ( S8→Sx2-→S22-+S2-)${{\rm{S}}_8}{\bm{ \to }}{\rm{S}}_{\rm{x}}^{2{\bm{ - }}}{\bm{ \to }}{\rm{S}}_2^{2{\bm{ - }}}{\bm{ + }}{{\rm{S}}^{2{\bm{ - }}}})$ , forming ZnS. On charging, the ZnS and short-chain polysulfides will oxidize back to elemental sulfur. This electrolyte design strategy and unique multi-step electrochemistry of the Zn/S system provide a new pathway in tackling both key issues of Zn dendritic growth and sulfur side reactions, and also in designing better Zn/S batteries in the future. Agency for Science, Technology and Research (A*STAR) National Research Foundation (NRF) The authors acknowledge the grant from the National Research Foundation of Singapore (NRF) Investigatorship Award NRFI2017-08/NRF2016NRF-NRFI001-22 and A*STAR under the Advanced Manufacturing and Engineering (AME) programmatic fund number A20H3g2140. 2023-06-26T01:47:19Z 2023-06-26T01:47:19Z 2023 Journal Article Guo, Y., Chua, R., Chen, Y., Cai, Y., Tang, E. J. J., Lim, N. J. J., Tran, T. H., Verma, V., Wong, M. W. & Srinivasan, M. (2023). Hybrid electrolyte design for high-performance zinc–sulfur battery. Small, e2207133-. https://dx.doi.org/10.1002/smll.202207133 1613-6810 https://hdl.handle.net/10356/168974 10.1002/smll.202207133 36971296 2-s2.0-85150929659 e2207133 en NRFI2017-08/NRF2016NRF-NRFI001-22 A20H3g2140 Small © 2023 Wiley-VCH GmbH. All rights reserved. |
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Engineering::Materials Aqueous Batteries Conversion Mechanism Guo, Yuqi Chua, Rodney Chen, Yingqian Cai, Yi Tang, Ernest Jun Jie Lim, Nicholas J. J. Tran, Thu Ha Verma, Vivek Wong, Ming Wah Srinivasan, Madhavi Hybrid electrolyte design for high-performance zinc–sulfur battery |
| description |
Rechargeable aqueous Zn/S batteries exhibit high capacity and energy density. However, the long-term battery performance is bottlenecked by the sulfur side reactions and serious Zn anode dendritic growth in the aqueous electrolyte medium. This work addresses the problem of sulfur side reactions and zinc dendrite growth simultaneously by developing a unique hybrid aqueous electrolyte using ethylene glycol as a co-solvent. The designed hybrid electrolyte enables the fabricated Zn/S battery to deliver an unprecedented capacity of 1435 mAh g-1 and an excellent energy density of 730 Wh kg-1 at 0.1 Ag-1 . In addition, the battery exhibits capacity retention of 70% after 250 cycles even at 3 Ag-1 . Moreover, the cathode charge-discharge mechanism studies demonstrate a multi-step conversion reaction. During discharge, the elemental sulfur is sequentially reduced by Zn to S2- ( S8→Sx2-→S22-+S2-)${{\rm{S}}_8}{\bm{ \to }}{\rm{S}}_{\rm{x}}^{2{\bm{ - }}}{\bm{ \to }}{\rm{S}}_2^{2{\bm{ - }}}{\bm{ + }}{{\rm{S}}^{2{\bm{ - }}}})$ , forming ZnS. On charging, the ZnS and short-chain polysulfides will oxidize back to elemental sulfur. This electrolyte design strategy and unique multi-step electrochemistry of the Zn/S system provide a new pathway in tackling both key issues of Zn dendritic growth and sulfur side reactions, and also in designing better Zn/S batteries in the future. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Guo, Yuqi Chua, Rodney Chen, Yingqian Cai, Yi Tang, Ernest Jun Jie Lim, Nicholas J. J. Tran, Thu Ha Verma, Vivek Wong, Ming Wah Srinivasan, Madhavi |
| format |
Article |
| author |
Guo, Yuqi Chua, Rodney Chen, Yingqian Cai, Yi Tang, Ernest Jun Jie Lim, Nicholas J. J. Tran, Thu Ha Verma, Vivek Wong, Ming Wah Srinivasan, Madhavi |
| author_sort |
Guo, Yuqi |
| title |
Hybrid electrolyte design for high-performance zinc–sulfur battery |
| title_short |
Hybrid electrolyte design for high-performance zinc–sulfur battery |
| title_full |
Hybrid electrolyte design for high-performance zinc–sulfur battery |
| title_fullStr |
Hybrid electrolyte design for high-performance zinc–sulfur battery |
| title_full_unstemmed |
Hybrid electrolyte design for high-performance zinc–sulfur battery |
| title_sort |
hybrid electrolyte design for high-performance zinc–sulfur battery |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/168974 |
| _version_ |
1772827250896404480 |