Flexible magnesium-ion-conducting solid poly-blend electrolyte films for magnesium-ion batteries

IF 2.8 4区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Materials Science: Materials in Electronics Pub Date : 2024-09-10 DOI:10.1007/s10854-024-13458-8

Pradeep Nayak, Ismayil, Y. N. Sudhakar, M. S. Murari

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Abstract

Solid biodegradable polymer electrolyte systems are considered the optimal choice for energy storage devices because they are both cost-effective and energy-efficient. A solid blend polymer electrolyte (SBPE) membrane capable of transporting magnesium ions was prepared using a mixture of 70 wt% methylcellulose, 30 wt% chitosan, and varying wt% magnesium perchlorate salt. X-ray diffraction analysis revealed an increase in the amorphous nature caused by the inclusion of Mg(ClO₄)₂ salt in the polymer blend matrix. A Fourier transform infrared spectroscopy study of samples containing varying salt concentrations revealed secondary interactions between polymer segments and salt, which provides the basis for energy density. Moreover, through impedance analysis, it was determined that the bulk resistance decreased with increasing salt concentration. The SBPE containing 30 wt% magnesium perchlorate exhibited the highest ionic conductivity, with a value of 2.49 × 10^–6 S cm⁻¹. A comprehensive evaluation of the ion transport parameters, including mobility, carrier density, and diffusion, was conducted for the prepared electrolyte samples. Notably, an ionic transference number (t_ion) of approximately 0.83 was observed for the SBPE sample with 30 wt% magnesium salt, indicating ions’ prevalence as the system’s primary charge carriers. Electrochemical analyses demonstrated that the SBPE with the highest ion conductivity possessed an electrochemical stability window (ESW) of 1.92 V. Additionally, the thermal characteristics of the samples were evaluated using thermogravimetric analysis (TGA) to assess the thermal stability of the electrolyte. Finally, the highest conducting polymer electrolyte was employed to construct a primary magnesium battery, and its discharge profile with different cathode materials was studied. Based on these findings, the current study suggests an environmentally friendly, biodegradable, and economically viable electrolyte option suitable for separator cum electrolytes in magnesium-ion batteries.

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用于镁离子电池的柔性镁离子传导固体多元共混电解质薄膜

固体可生物降解聚合物电解质系统被认为是储能设备的最佳选择，因为它们既经济又节能。利用 70 wt%的甲基纤维素、30 wt%的壳聚糖和不同 wt%的高氯酸镁盐的混合物，制备了一种能够传输镁离子的固体混合聚合物电解质（SBPE）膜。X 射线衍射分析表明，聚合物混合物基质中加入 Mg(ClO4)2 盐后，无定形性质增加。对含有不同浓度盐的样品进行的傅立叶变换红外光谱研究显示，聚合物片段与盐之间存在次级相互作用，这为能量密度提供了依据。此外，通过阻抗分析还确定，随着盐浓度的增加，体积电阻也会降低。含有 30 wt% 高氯酸镁的 SBPE 表现出最高的离子传导性，其值为 2.49 × 10-6 S cm-1。对制备的电解质样品进行了离子传输参数的综合评估，包括迁移率、载流子密度和扩散。值得注意的是，镁盐含量为 30 wt% 的 SBPE 样品的离子转移数（tion）约为 0.83，表明离子是该系统的主要电荷载体。电化学分析表明，离子导电率最高的 SBPE 具有 1.92 V 的电化学稳定窗口 (ESW)。此外，还使用热重分析 (TGA) 评估了样品的热特性，以评估电解质的热稳定性。最后，利用导电性最高的聚合物电解质构建了镁原电池，并研究了其与不同阴极材料的放电曲线。基于这些发现，当前的研究提出了一种环境友好、可生物降解且经济可行的电解质方案，适用于镁离子电池中的隔膜兼电解质。

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来源期刊

Journal of Materials Science: Materials in Electronics 工程技术-材料科学：综合

CiteScore

5.00

自引率

7.10%

发文量

1931

审稿时长

2 months

期刊介绍： The Journal of Materials Science: Materials in Electronics is an established refereed companion to the Journal of Materials Science. It publishes papers on materials and their applications in modern electronics, covering the ground between fundamental science, such as semiconductor physics, and work concerned specifically with applications. It explores the growth and preparation of new materials, as well as their processing, fabrication, bonding and encapsulation, together with the reliability, failure analysis, quality assurance and characterization related to the whole range of applications in electronics. The Journal presents papers in newly developing fields such as low dimensional structures and devices, optoelectronics including III-V compounds, glasses and linear/non-linear crystal materials and lasers, high Tc superconductors, conducting polymers, thick film materials and new contact technologies, as well as the established electronics device and circuit materials.