氧化石墨模板法研磨时间和石墨添加量对用于电解质应用的磷酸锡粉末形态结构的影响

Joseph Bona Nandito, Calvin Santo Arnoldus, Bachtiar Zuhdi Alfarizi, Bismo Aditiya Prakoso, A. Trenggono
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引用次数: 0

摘要

磷酸锡可用于电解液应用。近年来,固体电解质行业经历了大幅增长。2020 年,固体电解质行业的市场规模估计为 1,780 万美元,预计到 2030 年将达到 5,660 万美元,2021-2030 年的复合年增长率为 12.1%。固态电解质行业的增长主要受电池需求增长的推动。固态电池正在成为传统锂离子电池的一种有前途的替代品。本研究通过改良 Hummers 反应合成磷酸锡/GO,利用 GO 模板法控制合成材料的形态和晶体结构,并通过煅烧去除 GO,制备出磷酸锡纳米颗粒。研究结果表明,石墨研磨时间会影响生成的磷酸锡粉末的大小,氧化石墨烯(GO)模板的大小也会影响磷酸锡粉末的大小。研磨时间也会影响煅烧前后粉末的重量,以及产生的 GO 和磷酸锡的数量。石墨添加比例对煅烧前后磷酸锡/GO 样品的重量也有显著影响。2 克石墨与 1 克锡的添加比例可在煅烧后产生最佳重量的磷酸锡,这表明使用 GO 作为锡生长模板是有效的。此外,XRD 分析表明在所得粉末中发现了三种主要化合物相,即二锡(IV)三(磷酸盐(V))钾(KO12P3Sn2)、磷酸锡(SnP2O7)和铁酸钾(FeKO2)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effect of Milling Time and Addition of Graphite on the Morphological Structure of Tin Phosphate Powder Using the Graphine Oxide Template Method for Electrolyte Applications
Tin phosphate can be used for electrolyte applications. The solid electrolyte industry has experienced significant growth in recent years. In 2020, the market size of the solid electrolyte industry was estimated at $17.8 million and is expected to reach $56.6 million by 2030 at a CAGR of 12.1% from 2021 to 2030. The growth of the solid electrolyte industry is driven by the increasing demand for batteries. Solid-state batteries are becoming a promising alternative to conventional lithium-ion batteries. This research produces tin phosphate nanoparticles through the synthesis of tin phosphate/GO with a modification of the Hummers reaction, using the GO template method which is used to control the morphology and crystal structure of the synthesized material, and calcined to remove GO and produce tin phosphate powder. The research results show that graphite milling time influences the size of the tin phosphate powder produced, and the size of the Graphene Oxide (GO) template also influences the size of the tin phosphate powder. Grinding time also affects the weight of the powder before and after calcination, as well as the amount of GO and tin phosphate produced. The graphite addition ratio also had a significant effect on the weight of the tin phosphate/GO samples before and after calcination. The ratio of adding 2 grams of graphite to 1 gram of tin produces an optimal weight of tin phosphate after calcination, indicating the effectiveness of using GO as a tin growth template. In addition, XRD analysis showed the identification of three dominant compound phases in the resulting powder, namely potassium ditin (IV) tris(phosphate(V)) (KO12P3Sn2), tin phosphate (SnP2O7), and potassium ferrate (FeKO2).
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