钠离子电池层状Na2Mn3O7正极材料研究进展

L. Rakhymbay, Bagdaulet Shugay, Maksat Karlykan, Alibi Namazbay, Aishuak Konarov, Z. Bakenov
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摘要

人们越来越注意在日常业务范围内用于能源生产和储存的各种技术,从小规模应用到大规模应用,这些技术都同样重要。就储能系统而言,锂离子电池因其高能量和功率密度而成为市场领导者,使其成为最受欢迎的选择之一。尽管如此,从长远来看,锂资源和阴极材料所需的其他金属(如钴和镍)的稀缺是一个重大问题。最近的研究集中在替代能源存储系统上,以减轻这些担忧。由于钠的广泛可用性和与锂离子电池(lib)相似的化学性质,钠离子电池(sib)被认为是最有前途的下一代替代品。为了在当今市场上具有竞争力,需要开发高性能的正极材料。在所研究的材料中,Na2Mn3O7电极表现出较高的电容量。此外,钠和锰的低廉价格使其更具吸引力。本文综述了近年来研究和增强Na2Mn3O7正极材料的进展。
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Recent Advances in Layered Na2Mn3O7 Cathode Materials for Sodium-Ion Batteries
There has been an increasing amount of attention paid to the different technologies that are used in energy production and storage in the context of day-to-day operations, which range from small-scale applications to large-scale applications, which are all equally important. As far as energy storage systems are concerned, Li-ion batteries are the market leader due to their high energy and power density, making them one of the most popular choices. Despite this, a significant concern is the scarcity of lithium resources and other metals that are needed for cathode material, such as cobalt and nickel, in the long run. Recent research has focused on al-ternative energy storage systems to mitigate these concerns. Due to sodium's widespread availability and sim-ilar chemistry to lithium-ion batteries (LIBs), sodium-ion batteries (SIBs) are considered the most promising next-generation alternatives. Being competitive in the market today requires the development of cathode ma-terials that are of high performance. Among the studied materials, the Na2Mn3O7 electrode displayed high ca-pacity. In addition, the low price of sodium and manganese makes it even more attractive. In this work, we summarized the recent progress in studying and enhancing the Na2Mn3O7 cathode material.
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