Hofmeister Effect Mediated Conductivity of Hydrogel Electrolytes for High Performance Supercapacitor

IF 5.1 4区 材料科学 Q2 ELECTROCHEMISTRY
Bingxi Lv, Qingqing Guo, Xingxiang Ji, Ligang Gai, Libin Liu
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Abstract

Regulating the performance of hydrogel electrolytes by Hofmeister effect has attracted great interest. However, the Hofmeister effects of cations on the conductivity of hydrogel electrolytes are rarely reported. Here, hydrogel electrolytes (polySA) have been fabricated by random copolymerization of zwitterionic monomers in the presence of NH4Cl, NaCl and LiCl. The weak interaction between NH4+ with water and molecular chains makes polySA-NH4+ electrolyte have high conductivity at room temperatures, whereas the strong interaction between Li+ with water and molecular chains makes polySA-Li+ electrolyte possess good anti-freezing properties and high mechanical strength. The polySA-Li+ hydrogel electrolyte can have a conductivity of 9.63 mS cm−1 at −35 °C. Supercapacitors assembled with polySA-Li+ offers high specific capacitance of 52.25 F g−1 at 25 °C and 47.75 F g−1 at −35 °C. The capacitance retention is 94.64 % after 10 days at −35 °C. Our work shows that different properties of hydrogel electrolytes can be achieved by regulating Hofmeister effect, which provides a new way to prepare high-performance energy storage materials.

Abstract Image

用于高性能超级电容器的水凝胶电解质的霍夫迈斯特效应介导电导率
通过霍夫迈斯特效应调节水凝胶电解质的性能已引起人们的极大兴趣。然而,阳离子对水凝胶电解质电导率的霍夫迈斯特效应却鲜有报道。在此,我们在 NH4Cl、NaCl 和 LiCl 的存在下,通过无规共聚制造出了水凝胶电解质(polySA)。NH4+ 与水和分子链之间的弱相互作用使 polySA-NH4+ 电解质在室温下具有高电导率,而 Li+ 与水和分子链之间的强相互作用则使 polySA-Li+ 电解质具有良好的抗冻性和较高的机械强度。聚SA-Li+ 水凝胶电解质在 -35°C 时的电导率可达 9.63 mS cm-1。用 polySA-Li+ 组装的超级电容器在 25 ℃ 和 -35 ℃ 下分别具有 52.25 F g-1 和 47.75 F g-1 的高比电容。在零下 35 摄氏度条件下使用 10 天后,电容保持率为 94.64%。我们的工作表明,通过调节霍夫迈斯特效应可以实现水凝胶电解质的不同特性,这为制备高性能储能材料提供了一种新方法。
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来源期刊
CiteScore
8.60
自引率
5.30%
发文量
223
期刊介绍: Electrochemical energy storage devices play a transformative role in our societies. They have allowed the emergence of portable electronics devices, have triggered the resurgence of electric transportation and constitute key components in smart power grids. Batteries & Supercaps publishes international high-impact experimental and theoretical research on the fundamentals and applications of electrochemical energy storage. We support the scientific community to advance energy efficiency and sustainability.
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