提高钠离子电池中Maricite-NaMnPO4和Maricite-纳FePO4正极材料的电化学性能

IF 2.3 Q3 ELECTROCHEMISTRY International journal of electrochemistry Pub Date : 2023-01-27 DOI:10.1155/2023/6054452
I. Mohsin, Luca Schneider, Zheng Yu, Wenqing Cai, C. Ziebert
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引用次数: 0

摘要

聚阴离子正极材料NaMnPO4和NaFePO4分别存在于水镁石/钠长石和水镁石-橄榄石两种不同的相中。钠长石NaMnPO4和橄榄石NaFePO4都具有电化学活性,并具有钠离子迁移的一维隧道;然而,这两个相在热力学上是不稳定的。因此,它们可以通过电化学途径合成。相反,水镁石(m)-NaMnPO4和水镁石-NaFePO4是热力学稳定的形式,但它们的钠提取和插入晶体结构的扩散途径具有巨大的活化能,这阻碍了电化学反应。因此,已经研究了商用m-NaMnPO4和m-NaFePO4的电化学行为,以找到一种使它们电化学的方法。采用球磨和热/机械碳涂层来减小颗粒尺寸,以提高电化学性能并缩短扩散路径。此外,球磨会导致缺陷和部分相变。对研磨包覆的NaMnPO4和NaFePO4的电化学性能进行了深入的研究和比较。用差示扫描量热计研究了NaFePO4的相变。因此,通过颗粒尺寸的减小以及碳涂层,两种阴极材料的可实现容量都得到了显著提高,最高可达~50mAh.g−1。然而,这种材料中的副反应和团聚问题需要最小化,并且必须考虑到这一点,以使其能够应用。
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Enabling the Electrochemical Performance of Maricite-NaMnPO4 and Maricite-NaFePO4 Cathode Materials in Sodium-Ion Batteries
NaMnPO4 and NaFePO4, polyanion cathode materials, exist in two different phases maricite/natrophilite and maricite/olivine, respectively. Both natrophilite NaMnPO4 and olivine NaFePO4 are electrochemically active and possess a one-dimensional tunnel for sodium-ion migration; however, these two phases are thermodynamically unstable. Therefore, they can be synthesized through an electrochemical route. On the contrary, maricite (m)-NaMnPO4 and maricite (m)-NaFePO4 are thermodynamically stable forms but have a huge activation energy of their diffusion pathways for sodium extraction and insertion in the crystal structure, which hinders electrochemical reactions. Therefore, the electrochemical behaviour of commercial m-NaMnPO4 and m-NaFePO4 has been studied to find a way for enabling them electrochemically. Ball milling and thermal/mechanical carbon coating are employed to reduce the particle size to enhance the electrochemical performance and shorten the diffusion pathway. Moreover, ball milling leads to defects and partial phase transformation. The electrochemical performance of milled-coated NaMnPO4 and NaFePO4 has been thoroughly investigated and compared. The phase transition of NaFePO4 is revealed by a differential scanning calorimeter. As a result, the achievable capacities of both cathode materials are significantly enhanced up to ∼50 mAh.g−1 via the particle size reduction as well as by carbon coating. However, the side reactions and agglomeration problems in such materials need to be minimized and must be considered to enable them for applications.
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