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使用离子液体分散的锂离子钙钛矿的高能量密度固态对称超级电容器。

High energy density solid state symmetric supercapacitors using ionic liquid dispersed Li ion-perovskites.

作者信息

Sharma Bhargab, Sharma Shrishti, Kaur Gurpreet, Dalvi Anshuman

机构信息

Department of Physics, BITS Pilani-Pilani Campus RJ-333031 India

Department of Chemistry, BITS Pilani-Pilani Campus RJ-333031 India.

出版信息

RSC Adv. 2025 Jan 27;15(4):2704-2716. doi: 10.1039/d4ra07417c. eCollection 2025 Jan 23.

DOI:10.1039/d4ra07417c
PMID:39871967
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11770677/
Abstract

The study reports solid-state ceramic supercapacitors (SSCs) assembled using a novel composite electrolyte based on Li ion conducting perovskite-type LLTO (LiLaTiO) and an ionic liquid (EMIM BF). Small amounts of various ionic liquids (ILs) were added to LLTO to enhance the ionic conductivity and improve electrode compatibility. The optimal composition with approximately ∼6 wt% EMIM BF in LLTO exhibited a high ionic conductivity of around ∼10 Ω cm at room temperature, nearly three orders of magnitude higher than that of the pristine LLTO. Optimized electrolyte composition was therefore used for fabrication by compressing between high surface area activated carbon-coated copper electrodes and assembled in an affordable lamination cell geometry. The SSCs demonstrated stable cycling performance for at least 10 000 cycles at 2 V operating voltage and 1.13 A g (2 mA) discharge current, with a remarkably high coulombic efficiency of ∼99%. A typical laminated cell at 35 °C exhibited a specific capacitance of around 510 F g at 0.57 A g (1 mA), and 2 V. Supercapacitors operating below 2 V showed a pure electric double-layer type nature. A stack of 4 cells in series can power two white LEDs (6 V) for ∼40 minutes.

摘要

该研究报告了使用基于锂离子传导钙钛矿型LLTO(LiLaTiO)和离子液体(EMIM BF)的新型复合电解质组装的固态陶瓷超级电容器(SSC)。向LLTO中添加少量各种离子液体(IL)以提高离子电导率并改善电极兼容性。在LLTO中含有约6 wt% EMIM BF的最佳组合物在室温下表现出约10 Ω cm的高离子电导率,比原始LLTO高近三个数量级。因此,通过在高表面积活性炭涂覆的铜电极之间压缩来使用优化的电解质组合物进行制造,并以经济实惠的层压电池几何结构进行组装。这些SSC在2 V工作电压和1.13 A g(2 mA)放电电流下表现出至少10000次循环的稳定循环性能,库仑效率高达约99%。一个典型的层压电池在35°C、0.57 A g(1 mA)和2 V时表现出约510 F g的比电容。在2 V以下工作的超级电容器表现出纯双电层类型的性质。4个串联的电池组可为两个白色LED(6 V)供电约40分钟。

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