| Full text | |
| Author(s): |
Silva, Vinicius D.
;
Melo, Eduardo C.
;
Martins, Vitor L.
;
de Oliveira, Paulo F. M.
;
Ando, Romulo A.
;
Catalani, Luiz H.
;
Torresi, Roberto M.
Total Authors: 7
|
| Document type: | Journal article |
| Source: | NANO ENERGY; v. 136, p. 14-pg., 2025-04-01. |
| Abstract | |
Hard carbon (HC) has been the most promising negative electrode candidate for sodium-ion batteries (SIBs). However, its microstructure still needs to be optimized and better understood to improve sodium-ion storage and thus achieve widespread commercialization. In this study, self-supporting HC nanofibers as negative electrodes for SIBs were thoroughly investigated. This research focused on understanding the influence of the carbonization temperature (1000-1600 degrees C) on the microstructure and electrochemical performance. Higher carbonization temperatures result in more organized microstructures with fewer defects but do not necessarily result in the best specific capacity. Therefore, the HC nanofibers obtained at 1400 degrees C showed the best balance between the slope (adsorption) and plateau (intercalation) capacities, suggesting an optimized microstructure for sodium-ion storage. Additionally, operando Raman spectroscopy, GITT and ex situ HRTEM analysis were used to elucidate the Na+ storage mechanism, and the results suggested a multistage process involving adsorption, intercalation, and pore filling. In a practical comparison, self-supporting HC electrodes outperformed traditional ink- based HC electrodes; the corresponding reversible capacity and initial Coulombic efficiency (ICE) was 363 mAh g(-1) (78 %) for the HC14-nanofiber but only 98 mAh g(-1) (36 %) for the HC14-ink. This drastic reduction in the electrochemical performance of the ink-based electrode is due to microstructural modifications imposed by the conventional processing steps and the loss of microporosity caused by binder infiltration. This work contributes to the understanding of the Na+ storage mechanisms in HCs and highlights the potential of selfsupporting HC nanofibrous electrodes for high-performance SIBs. (AU) | |
| FAPESP's process: | 22/11983-4 - Spectroscopy signal enhancement: nanomaterials, theory, and computer simulation |
| Grantee: | Mauro Carlos Costa Ribeiro |
| Support Opportunities: | Research Projects - Thematic Grants |
| FAPESP's process: | 22/12609-9 - Hard carbon nanofibers as a self-supporting negative electrode for the next generation of sodium-ion batteries |
| Grantee: | Vinícius Dias Silva |
| Support Opportunities: | Scholarships in Brazil - Post-Doctoral |
| FAPESP's process: | 21/00675-4 - Tying up materials for electrochemical energy storage and catalysis |
| Grantee: | Roberto Manuel Torresi |
| Support Opportunities: | Research Projects - Thematic Grants |
| FAPESP's process: | 20/14955-6 - Designing the next generation of advanced multicomponent materials through mechanochemical synthesis |
| Grantee: | Paulo Filho Marques de Oliveira |
| Support Opportunities: | Research Grants - Young Investigators Grants |
| FAPESP's process: | 19/26309-4 - Beyond Li-ion: development of reversible non-aqueous metal-air batteries |
| Grantee: | Vitor Leite Martins |
| Support Opportunities: | Research Grants - Young Investigators Grants |