Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries
The development of polymer sodium batteries requires cathode materials with stable interfaces to avoid poor interfacial contact and interfacial side reactions during cycling. Here, a co-engineering strategy is deployed to tailor the cathode internal structure and improve the cathode interface stabil...
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sg-ntu-dr.10356-1664042023-04-24T07:37:05Z Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries Pan, Jun Hu, Lulu Zhang, Yuchen Zhang, Tao Wang, Nana Dou, Shixue Fan, Hong Jin School of Physical and Mathematical Sciences Science::Physics Crystal Structural Stability Polymer Sodium Batteries The development of polymer sodium batteries requires cathode materials with stable interfaces to avoid poor interfacial contact and interfacial side reactions during cycling. Here, a co-engineering strategy is deployed to tailor the cathode internal structure and improve the cathode interface stability through bonding interactions. Internally, the effect of low-cost Fe substitution in the obtained Na0.67Mn2/3Fe1/3O2 cathode material renders favorable effects in several aspects. First, the increased lattice constant facilitates Na+ intercalation and thereby lowers the diffusion barrier of Na+ ions. Second, it increases the electronic conductivity, thereby improving the reaction reversibility. Third, the Mn O bond length is shortened, which alleviates the Jahn-Taylor effect and improves structural stability. In addition to these internal effects, the Fe O B bond interactions due to Fe substitution promote the decomposition of the tris(trimethylsilane)borate additive and the formation of a dense and uniform cathode electrolyte interface film, leading to improved cycling stability. Owing to the co-engineering of both internal structure and surface modification, the polymer solid-state sodium battery with a stable interface exhibits a specific capacity of 85.2 mAh g-1 after 800 cycles at 1 C. Ministry of Education (MOE) This work was financially supported by the National Nature Science Foundation of China (No. 22209199). H.J.F. acknowledges the financial support from Ministry of Education, Singapore, through its Academic Research Fund Tier 1 (RG85/20) and Tier 2 (MOE-T2EP50121-0006). 2023-04-24T07:37:05Z 2023-04-24T07:37:05Z 2023 Journal Article Pan, J., Hu, L., Zhang, Y., Zhang, T., Wang, N., Dou, S. & Fan, H. J. (2023). Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries. Advanced Functional Materials. https://dx.doi.org/10.1002/adfm.202214904 1616-301X https://hdl.handle.net/10356/166404 10.1002/adfm.202214904 2-s2.0-85149315489 en RG85/20 MOE-T2EP50121-0006 Advanced Functional Materials © 2023 Wiley-VCH GmbH. All rights reserved. |
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Science::Physics Crystal Structural Stability Polymer Sodium Batteries Pan, Jun Hu, Lulu Zhang, Yuchen Zhang, Tao Wang, Nana Dou, Shixue Fan, Hong Jin Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| description |
The development of polymer sodium batteries requires cathode materials with stable interfaces to avoid poor interfacial contact and interfacial side reactions during cycling. Here, a co-engineering strategy is deployed to tailor the cathode internal structure and improve the cathode interface stability through bonding interactions. Internally, the effect of low-cost Fe substitution in the obtained Na0.67Mn2/3Fe1/3O2 cathode material renders favorable effects in several aspects. First, the increased lattice constant facilitates Na+ intercalation and thereby lowers the diffusion barrier of Na+ ions. Second, it increases the electronic conductivity, thereby improving the reaction reversibility. Third, the Mn O bond length is shortened, which alleviates the Jahn-Taylor effect and improves structural stability. In addition to these internal effects, the Fe O B bond interactions due to Fe substitution promote the decomposition of the tris(trimethylsilane)borate additive and the formation of a dense and uniform cathode electrolyte interface film, leading to improved cycling stability. Owing to the co-engineering of both internal structure and surface modification, the polymer solid-state sodium battery with a stable interface exhibits a specific capacity of 85.2 mAh g-1 after 800 cycles at 1 C. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Pan, Jun Hu, Lulu Zhang, Yuchen Zhang, Tao Wang, Nana Dou, Shixue Fan, Hong Jin |
| format |
Article |
| author |
Pan, Jun Hu, Lulu Zhang, Yuchen Zhang, Tao Wang, Nana Dou, Shixue Fan, Hong Jin |
| author_sort |
Pan, Jun |
| title |
Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| title_short |
Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| title_full |
Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| title_fullStr |
Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| title_full_unstemmed |
Internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| title_sort |
internal and external co-engineering of stable cathode interface improves cycle performance of polymer sodium batteries |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/166404 |
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1764208179970834432 |