研究Li 3ocl反钙钛矿作为锂离子电池固体电解质合成过程中还原Li x (OH) y Cl z氢氧化物相的水用量

Aref Ghanbari, Zahra Khakpour, Aida Faeghinia, Abouzar Massoudi
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引用次数: 0

摘要

摘要采用水热法制备了Li3OCl固体电解质。为了考察水对Li3OCl相稳定性的影响和减少二次氢氧化物相的数量,在合成过程中向前驱体中加入不同摩尔比的水。XRD、DSC、FE-SEM、EIS和CV等技术表明,LiCl: LiOH: H2O(1:2:10)的摩尔比具有较好的相稳定性和较少的不需要的氢氧化物相。DSC结果还表明,在第一次热处理循环中,Lix(OH)yClz相转变为Li3OCl相。热处理后的最终结构为玻璃陶瓷结构。在60°C和110°C时,合成的Li3OCl离子电导率分别达到5.0 × 10−2 mS cm−1和0.76 mS cm−1。合成的Li3OCl在60 ~ 110℃温度范围内的活化能为0.27 eV。在130°C下,从−1.5 V到4 V的锂化/脱氧过程中,证实了合成的Li3OCl的化学稳定性。关键词:抗钙钛矿电化学稳定性水热合成氢氧相固体电解质感谢伊朗材料与能源研究中心对这项工作的支持。披露声明作者未报告潜在的利益冲突。研究、材料准备、实验部分、数据收集、数据解释和原创稿件撰写由Aref Ghanbari完成。监督,资金获取,概念化,结果解释,手稿审查和出版版本批准由Zahra Khakpour进行。监督、方法和资金获取由Aida Faeghinia和Abouzar Massoudi完成。所有作者都已阅读并同意稿件的出版版本。数据可用性声明所有数据和分析均可根据要求提供。没有来自政府、商业或非营利部门的资助机构为这项研究提供任何特定的资助。没有来自政府、商业或非营利部门的资助机构为本研究提供任何特定的资助。作者简介:aref Ghanbari,陶瓷系材料与能源研究中心博士生。本文主要研究固态锂离子电池的储能问题。Zahra KhakpourDr。Zahra Khakpour,通讯作者,材料与能源研究中心助理教授。她的研究领域包括燃料电池、电池和光催化剂系统中的材料和纳米材料表征。Aida FaeghiniaDr。Aida Faeghinia,现任材料与能源研究中心副教授。Abouzar MassoudiDr。Abouzar Massoudi,现任材料与能源研究中心助理教授。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigating the amount of water on reducing Li x (OH) y Cl z hydroxide phases in the synthesis of Li 3 OCl anti-perovskite as a solid electrolyte in Li-ion batteries
ABSTRACTThe Li3OCl solid electrolyte was synthesized in the present study via the hydrothermal method. In order to investigate the effect of water on the stability of the Li3OCl phase and reduce the amount of secondary hydroxide phases, different molar ratios of water were added to the precursors during the synthesis procedures. Employing XRD, DSC, FE-SEM, EIS, and CV techniques revealed that the LiCl: LiOH: H2O (1:2:10) molar ratio has better phase stability and fewer undesired hydroxide phases. The DSC results also showed that during the first heat treatment cycle, the Lix(OH)yClz phases were converted to the Li3OCl phase. After heat treatment, the final structure was characterized as a glass-ceramic structure. At 60°C and 110°C, respectively, the synthesized Li3OCl reached an ionic conductivity of 5.0 × 10−2 mS cm−1 and 0.76 mS cm−1. Also, the activation energy of 0.27 eV in the 60–110°C temperature range was recorded for the synthesized Li3OCl. The chemical stability of the synthesized Li3OCl was confirmed during lithiation/delithiation from −1.5 to 4 V at 130°C.KEYWORDS: Anti-perovskiteelectrochemical stabilityhydrothermal synthesishydroxide phasessolid electrolytes AcknowledgementsWe thank the Materials and Energy Research Center, Iran, for the support of this work.Disclosure statementNo potential conflict of interest was reported by the author(s).Author contributionsResearch, material preparation, experimental sections, data collection, data interpretation, and original manuscript writing were done by Aref Ghanbari. Supervision, funding acquisition, conceptualization, results interpretation, manuscript reviewing, and publication-version approval are conducted by Zahra Khakpour. Supervision, methodology, and funding acquisition were done by Aida Faeghinia and Abouzar Massoudi.All authors have read and agreed to the published version of the manuscript.Data availability statementAll data and analysis are available upon request.Additional informationFundingNo funding institutions from the governmental, commercial, or nonprofit sectors contributed any specific grants for this study. No funding institutions from the governmental, commercial, or nonprofit sectors contributed any specific grants for this study.Notes on contributorsAref GhanbariAref Ghanbari, P.h.D student at Materials and Energy Research Center, Ceramic Department. The thesis is concerned with the energy storage, and Li-ion solid state batteries problems.Zahra KhakpourDr. Zahra Khakpour, is the corresponding author and is an assistant professor at Materials and Energy Research Center. She worked as a research scientist in area includes materials and nanomaterials characterization in the Fuel cell, batteries and photo catalyst systems.Aida FaeghiniaDr. Aida Faeghinia, is currently associate Professor at Materials and Energy Research Center.Abouzar MassoudiDr. Abouzar Massoudi, is currently assistant Professor at Materials and Energy Research Center.
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