説明:
(abstract)We investigate spinel-type MgV2O4 (MVO) as a cathode material and elucidate the correlation between its crystal structure and electrochemical performance. An ordered spinel was synthesized via a solid-state route and subsequently subjected to mechanical milling (MM), while a solvothermal (ST) method was employed to prepare a comparative sample. Rietveld refinement revealed that MM induces a transition from an ordered to a disordered spinel structure, accompanied by partial V occupancy at the interstitial 16c site, which obstructs Mg2+ migration between 8a sites. Despite particle size reduction, MM-MVO exhibited poor reversibility due to
this structural disorder. Complementary computational analysis confirmed the energetic favorability of V migration into the 16c site by MM, explaining the origin of the diffusion barrier. In contrast, ST-MVO retained a relatively ordered structure with minimal V occupation at 16c sites and delivered a reversible capacity of 175 mAh g−1 at 2 V when paired with a high-voltage electrolyte. These findings highlight the critical role of spinel ordering in enabling efficient Mg2+ transport and provide design guidelines for high performance MRB cathodes.
権利情報:
キーワード: Rechargeable magnesium batteries, Cathode, Crystal structure, Solvothermal treatment, Mechanical milling
刊行年月日: 2026-02-11
出版者: Royal Society of Chemistry (RSC)
掲載誌:
研究助成金:
原稿種別: 出版者版 (Version of record)
MDR DOI:
公開URL: https://doi.org/10.1039/d5ta09602b
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その他の識別子:
連絡先:
更新時刻: 2026-03-24 12:59:40 +0900
MDRでの公開時刻: 2026-03-24 16:24:16 +0900
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90_Ishida_JMCA 2026_MgV2O4 spinel.pdf
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サイズ | 1.33MB | 詳細 |