New glass cathode materials for Li-ion battery: Ni-Co doping in Li-B-O based glass

Q1 Materials Science

Materials Science for Energy Technologies Pub Date : 2023-01-01 DOI:10.1016/j.mset.2023.05.005

Sumeth Siriroj , Jintara Padchasri , Amorntep Montreeuppathum , Jidapa Lomon , Narong Chanlek , Yingyot Poo-arporn , Prayoon Songsiriritthigul , Supree Pinitsoontorn , Saroj Rujirawat , Pinit Kidkhunthod

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Abstract

Lithium-borate-based glass co-doped with nickel and cobalt ions was successfully fabricated by a two-step melt quenching method. The relationship between Ni and Co contents in the glasses was investigated, with a focus on their electrochemical properties and battery performance. Cyclic voltammetry was used to pre-investigate the electrochemical properties of the glass electrodes. It was found that the specific capacitance of all conditions was above 100 F/g. This preliminary study showed that the glass is feasible to use as a Li-ion battery cathode. The Co-rich content sample (NC11) exhibited the highest specific capacity of 380 mAh/g in the first cycle test. However, the specific capacity was dramatically decreased in subsequent cycles due to Li-ion trapping in the glass structure. Additionally, the higher amount of Ni ions in the co-doping Ni/Co-LBO glass enhanced the retention properties. This suggests that Ni-rich content could improve the release of free Li-ions from the host glass structure.

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新型锂离子电池玻璃正极材料:镍钴掺杂锂硼氧基玻璃

采用两步熔体淬火法制备了镍钴离子共掺杂硼酸锂基玻璃。研究了玻璃中Ni和Co含量的关系，重点研究了玻璃的电化学性能和电池性能。采用循环伏安法对玻璃电极的电化学性能进行了预研究。结果表明，各工况下的比电容均在100 F/g以上。初步研究表明，该玻璃作为锂离子电池正极材料是可行的。在第一次循环测试中，富钴样品(NC11)的比容量最高，为380 mAh/g。然而，在随后的循环中，由于锂离子在玻璃结构中被捕获，比容量急剧下降。此外，在共掺杂的Ni/Co-LBO玻璃中，较高含量的Ni离子增强了玻璃的保留性能。这表明富镍含量可以促进游离锂离子从主体玻璃结构中释放出来。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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