Junmei Luo, Shufeng Bo, Seohyun Park, Beom-Kyeong Park, Oi Lun Li
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引用次数: 0
摘要
硒化铁具有高容量和优异的化学特性,一直被认为是碱金属离子电池的理想阳极。然而,由于体积膨胀导致的动力学迟钝和容量衰减,阻碍了其进一步发展。在此,通过简便的等离子体工程技术调整铁物种的数量,再经过简单的硒化转化过程,成功合成了一系列 FeSe2 纳米粒子(NPs)-封装碳复合材料。这种稳定的结构可有效缓解体积变化并加速动力学过程,从而实现优异的电化学性能。优化后的电极(FeSe2@C2)在 150 次循环后显示出出色的可逆容量(853.1 mAh g-1),在 5.0 A g-1 的锂+存储条件下显示出卓越的速率容量(444.9 mAh g-1)。在 Na+ 电池中,它在 0.1 A g-1 时具有相对较高的 433.7 mAh g-1 容量和良好的循环稳定性。等离子体工程化的 FeSe2@C2 复合材料得益于小尺寸 FeSe2 NPs 和大比表面积碳骨架的协同效应,在各种动力学分析中表现出卓越的离子/电子传输能力,并揭示了以表面介导的电容行为为主导的储能机制。这种新型低成本合成策略可为开发过渡金属基复合材料储能材料提供有价值的指导。
Plasma-engineered FeSe2-encapsulated carbon composites with enhanced kinetics for high-performance lithium and sodium ion batteries
Iron selenides with high capacity and excellent chemical properties have been considered as outstanding anodes for alkali metal-ion batteries. However, its further development is hindered by sluggish kinetics and fading capacity caused by volume expansion. Herein, a series of FeSe2 nanoparticles (NPs)-encapsulated carbon composites were successfully synthesized by tailoring the amount of Fe species through facile plasma engineering and followed by a simple selenization transformation process. Such a stable structure can effectively mitigate volume changes and accelerate kinetics, leading to excellent electrochemical performance. The optimized electrode (FeSe2@C2) exhibits outstanding reversible capacity of 853.1 mAh g−1 after 150 cycles and exceptional rate capacity of 444.9 mAh g−1 at 5.0 A g−1 for Li+ storage. In Na+ batteries, it possesses a relatively high capacity of 433.7 mAh g−1 at 0.1 A g−1 as well as good cycle stability. The plasma-engineered FeSe2@C2 composite, which profits from synergistic effect of small FeSe2 NPs and carbon framework with large specific surface area, exhibits remarkable ions/electrons transportation abilities during various kinetic analyses and unveils the energy storage mechanism dominated by surface-mediated capacitive behavior. This novel cost-efficient synthesis strategy might offer valuable guidance for developing transition metal-based composites towards energy storage materials.
期刊介绍:
Carbon Letters aims to be a comprehensive journal with complete coverage of carbon materials and carbon-rich molecules. These materials range from, but are not limited to, diamond and graphite through chars, semicokes, mesophase substances, carbon fibers, carbon nanotubes, graphenes, carbon blacks, activated carbons, pyrolytic carbons, glass-like carbons, etc. Papers on the secondary production of new carbon and composite materials from the above mentioned various carbons are within the scope of the journal. Papers on organic substances, including coals, will be considered only if the research has close relation to the resulting carbon materials. Carbon Letters also seeks to keep abreast of new developments in their specialist fields and to unite in finding alternative energy solutions to current issues such as the greenhouse effect and the depletion of the ozone layer. The renewable energy basics, energy storage and conversion, solar energy, wind energy, water energy, nuclear energy, biomass energy, hydrogen production technology, and other clean energy technologies are also within the scope of the journal. Carbon Letters invites original reports of fundamental research in all branches of the theory and practice of carbon science and technology.