Rongrong Chu, Thanh Tuan Nguyen, Yanqun Bai, Nam Hoon Kim, Joong Hee Lee
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引用次数: 62
摘要
可充电锂硫电池(LSBs)由于具有较高的理论比容量和能量密度,被认为是下一代储能设备的理想选择。然而,硫的绝缘性、Li2S2/Li2S的绝缘性以及高阶多硫化锂(LiPSs)的穿梭效应阻碍了其实际应用。本文探索了一种异质结构来提高LiPSs的转化反应动力学和吸附能力。通过合理设计导电碳骨架和极性金属位,实验和理论结果均表明,该材料对溶解的LiPSs具有较强的吸附能力,促进了转化反应速率。CoSe2/Co3O4@NC-CNT/S阴极具有优异的倍率性能(0.1℃时≈1457 mAh g−1,5℃时仍保持≈688 mAh g−1),在2℃下长期稳定充放电时,CoSe2/Co3O4@NC-CNT/S阴极具有≈780 mAh g−1的高初始比容量,500次循环后仍保持≈602 mAh g−1,库仑效率为≈95.4%。值得注意的是,即使在非常高的硫负载(≈10.1 mg cm−2)和稀薄的电解质条件下,电池也可以完全工作。本工作强调了合理设计异质结构的新策略,以促进lsdb的工业应用。
Uniformly Controlled Treble Boundary Using Enriched Adsorption Sites and Accelerated Catalyst Cathode for Robust Lithium–Sulfur Batteries
Rechargeable lithium–sulfur batteries (LSBs) are recognized as a promising candidate for next-generation energy storage devices because of their high theoretical specific capacity and energy density. However, the insulating of sulfur, Li2S2/Li2S, and the shuttling effect of high order lithium polysulfides (LiPSs) hinder its practical applications. Herein, a heterostructure is explored to enhance the conversion reaction kinetics and adsorption ability of LiPSs. By rationally designing a conductive carbon framework and polar metal sites, both experimental and theoretical results show strong adsorption abilities for dissolved LiPSs and promote the conversion reaction rate. A CoSe2/Co3O4@NC-CNT/S cathode shows an excellent rate performance (≈1457 mAh g−1 at 0.1 C and still retains ≈688 mAh g−1 at a high rate of 5 C). When performing charge–discharge in long-term stability at 2 C, the CoSe2/Co3O4@NC-CNT/S cathode delivers a high initial specific capacity of ≈780 mAh g−1 and retains ≈602 mAh g−1 after 500 cycles with an excellent Coulombic efficiency of ≈95.4%. Remarkably, the battery can entirely operate even at a very high sulfur loading of ≈10.1 mg cm−2 and lean electrolyte condition. This work emphasizes a new strategy to rationally design heterostructures that can encourage the industrial application of LSBs.
期刊介绍:
Established in 2011, Advanced Energy Materials is an international, interdisciplinary, English-language journal that focuses on materials used in energy harvesting, conversion, and storage. It is regarded as a top-quality journal alongside Advanced Materials, Advanced Functional Materials, and Small.
With a 2022 Impact Factor of 27.8, Advanced Energy Materials is considered a prime source for the best energy-related research. The journal covers a wide range of topics in energy-related research, including organic and inorganic photovoltaics, batteries and supercapacitors, fuel cells, hydrogen generation and storage, thermoelectrics, water splitting and photocatalysis, solar fuels and thermosolar power, magnetocalorics, and piezoelectronics.
The readership of Advanced Energy Materials includes materials scientists, chemists, physicists, and engineers in both academia and industry. The journal is indexed in various databases and collections, such as Advanced Technologies & Aerospace Database, FIZ Karlsruhe, INSPEC (IET), Science Citation Index Expanded, Technology Collection, and Web of Science, among others.
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