Chunyi Xu, Song Sun, Xin Zhang, Hongfei Zhang, Chaoqun Xia, Shijing Zhao, Hua Wang, Huiyang Gou, Gongkai Wang
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引用次数: 0
摘要
微小合金颗粒作为高能量密度电池的阳极具有广阔的应用前景,但其快速充电和长周期稳定性受到体积扩散迟缓、应力响应差和电极/电解质界面不可控等因素的严重影响。在此,我们开发了一种具有工程共晶相界(PBs)的微尺寸铋硒合金颗粒模型系统,可为钠离子电池(SIBs)提供高能量密度、快速充电能力和长周期稳定性。具有宽敞原子错位的共晶相界可有效提高体扩散性,从而促进离子的快速扩散。PBs 诱导的异步多步合金化机制不仅能通过释放应力维持颗粒的永久合金化驱动力,还能通过改变结构演化过程提高颗粒的机械稳健性和界面稳定性。Bi6Sn4 阳极在 8 A g-1 (20C) 时可提供 407 mAh g-1 的快速充电能力,甚至可与已报道的纳米级合金阳极相媲美。该电极还能实现 2.1 g cm-3 的高分接密度和 1226 mAh cm-3 的体积容量,显示出实用潜力。本研究结果为通过微尺寸合金颗粒的 PBs 工程实现高能量 SIB 的快速充电和耐用性提供了启示。
Microsized alloying particles with engineered eutectic phase boundaries enable fast charging and durable sodium storage
Microsized alloying particles have broad application prospects as anodes of high energy density batteries, but their fast charging and long cyclic stability are seriously affected by the sluggish bulk diffusivity, poor stress response and uncontrolled electrode/electrolyte interface. Herein, we develop a microsized Bi-Sn alloying particle model system with the engineered eutectic phase boundaries (PBs) that provide high energy density, fast charging capability, and long cyclic stability for sodium ion batteries (SIBs). PBs with spacious atomic misalignment can effectively promote the bulk diffusivity, which facilitates the fast ion diffusion. The asynchronous multi-step alloying mechanism induced by PBs can not only maintain the permanent alloying driving force of particles by releasing stress, but also improve the mechanical robustness and interface stability of particles by changing the process of structure evolution. The Bi6Sn4 anode delivers a fast charging capability of 407 mAh g−1 at 8 A g−1 (20C), comparable even to the reported nano-sized alloy anodes. The electrode can also achieve a high tap density of 2.1 g cm−3 and a volumetric capacity of 1226 mAh cm−3, indicating a practical potential. The present results offer insights into the fast charging and durability for high energy SIBs by PBs engineering of microsized alloying particles.
期刊介绍:
Energy Storage Materials is a global interdisciplinary journal dedicated to sharing scientific and technological advancements in materials and devices for advanced energy storage and related energy conversion, such as in metal-O2 batteries. The journal features comprehensive research articles, including full papers and short communications, as well as authoritative feature articles and reviews by leading experts in the field.
Energy Storage Materials covers a wide range of topics, including the synthesis, fabrication, structure, properties, performance, and technological applications of energy storage materials. Additionally, the journal explores strategies, policies, and developments in the field of energy storage materials and devices for sustainable energy.
Published papers are selected based on their scientific and technological significance, their ability to provide valuable new knowledge, and their relevance to the international research community.
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