AI Article Synopsis

  • Sodium-ion batteries (SIBs) are emerging alternatives to lithium-ion batteries due to recent advancements in materials innovation, but current graphite anodes face limitations in performance.
  • Research is focusing on modifying transition metal selenides as anodes to address issues like poor cycling life caused by volume changes during sodium-ion processes.
  • The review highlights strategies for improving the electronic structures of these materials, which can boost their performance metrics such as charging speed, stability, and efficiency in SIB applications.

Article Abstract

In recent years, sodium-ion batteries (SIBs) have gained a foothold in specific applications related to lithium-ion batteries, thanks to continuous breakthroughs and innovations in materials by researchers. Commercial graphite anodes suffer from small interlayer spacing (0.334 nm), limited specific capacity (200 mAh g), and low discharge voltage (<0.1 V), making them inefficient for high-performance operation in SIBs. Hence, the current research focus is on seeking negative electrode materials that are compatible with the operation of SIBs. Many studies have been reported on the modification of transition metal selenides as anodes in SIBs, mainly targeting the issue of poor cycling life attributed to the volume expansion of the material during sodium-ion extraction and insertion processes. However, the intrinsic electronic structure of transition metal selenides also influences electron transport and sodium-ion diffusion. Therefore, modulating their electronic structure can fundamentally improve the electron affinity of transition metal selenides, thereby enhancing their rate performance in SIBs. This work provides a comprehensive review of recent strategies focusing on the modulation of electronic structures and the construction of heterogeneous structures for transition metal selenides. These strategies effectively enhance their performance metrics as electrodes in SIBs, including fast charging, stability, and first-cycle coulombic efficiency, thereby facilitating the development of high-performance SIBs.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11243387PMC
http://dx.doi.org/10.3390/molecules29133083DOI Listing

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