Mg-Composition Dependent Cycle Stability in Zn1-xMgxO Li-ion Battery: Transition from Electronic Transport-Limited to Ionic Transport Limited Cycles

IF 1.1 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Korean Journal of Metals and Materials Pub Date : 2024-05-05 DOI:10.3365/kjmm.2024.62.5.377

Byoungnam Park

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Abstract

This study explores Mg-composition dependent cycle stability in a Zn1-xMgxO Li-ion battery, where battery cycles transition from an electronic transport-limited to an ionic transport limited regime. We investigated the impact of Mg doping in Zn1-xMgxO nanocrystals on Li-ion battery performance, focusing on Mg compositions between x=0.05 and x=0.15. Mg composition dependent structural and electrical properties were explored using field effect transistors (FETs) and various microscopic/spectroscopic methods. The electronic conductivity was found to be sensitive to changes in Mg composition. Consistently, the initial capacity decreased with an increase in Mg composition, aligning with the reduction in electronic conductivity due to Mg doping. However, with successive cycles, the capacity became independent of the electronic conductivity, an outcome attributed to the formation of a solid-electrolyte interphase (SEI) and the conversion reactions. Initially, Mg doping reduces electronic conductivity due to increased carrier trapping, leading to lower discharge capacity. However, as cycling progresses, the impact of Mg doping diminishes. The formation of the SEI layer becomes more influential, significantly affecting Li-ion transport. Over time, factors like SEI formation, conversion reaction dynamics, and structural changes within the electrode start to dominate the battery's capacity, rather than the initial electronic conductivity influenced by Mg doping. This understanding can guide the development of materials with lower resistance, facilitating faster charging and discharging rates. More importantly, this study indicates that the initial capacity is closely tied to the conductivity of the Zn1-xMgxO material.

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Zn1-xMgxO 锂离子电池中与镁组成有关的循环稳定性：从电子传输受限循环到离子传输受限循环的转变

本研究探讨了 Zn1-xMgxO 锂离子电池中与镁成分有关的循环稳定性，电池循环从电子传输受限状态过渡到离子传输受限状态。我们研究了 Zn1-xMgxO 纳米晶体中掺杂镁对锂离子电池性能的影响，重点研究了 x=0.05 和 x=0.15 之间的镁成分。利用场效应晶体管（FET）和各种显微镜/光谱法探讨了与镁成分有关的结构和电学特性。研究发现，电子传导性对镁成分的变化非常敏感。一致的是，初始容量随着镁成分的增加而降低，这与掺杂镁导致的电子电导率降低相一致。然而，随着连续循环的进行，容量变得与电子电导率无关，这一结果归因于固体电解质间相（SEI）的形成和转换反应。最初，由于载流子捕获增加，掺入镁会降低电子电导率，从而导致放电容量降低。然而，随着循环的进行，掺镁的影响逐渐减弱。SEI 层的形成影响更大，会显著影响锂离子传输。随着时间的推移，SEI 的形成、转换反应动力学以及电极内部的结构变化等因素开始主导电池的容量，而不是受掺镁影响的初始电子导电性。这种认识可以指导开发电阻更低的材料，从而加快充放电速度。更重要的是，这项研究表明，初始容量与 Zn1-xMgxO 材料的电导率密切相关。

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来源期刊

Korean Journal of Metals and Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-METALLURGY & METALLURGICAL ENGINEERING

CiteScore

1.80

自引率

58.30%

发文量

100

审稿时长

4-8 weeks

期刊介绍： The Korean Journal of Metals and Materials is a representative Korean-language journal of the Korean Institute of Metals and Materials (KIM); it publishes domestic and foreign academic papers related to metals and materials, in abroad range of fields from metals and materials to nano-materials, biomaterials, functional materials, energy materials, and new materials, and its official ISO designation is Korean J. Met. Mater.