复合阴极纵向空间电荷转移优化实现超稳定全固态电池

IF 30.8 1区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Energy & Environmental Science Pub Date : 2025-07-29 DOI:10.1039/d5ee03407h

Junwei Liang, Kun Qian, Caijin Xiao, Yuhang Li, Zhichun Si, Lin Zeng, Songbai Han, Feiyu Kang, Yan-Bing He, Ming Liu

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引用次数: 0

摘要

全固态电池（assb）具有高能量密度和固有安全性，但在纵向阴极上复杂的电荷转移过程中面临着严峻的挑战。在这里，通过多物理场模拟，首次揭示了电荷转移对电化学反应非均质性的关键控制，决定了反应沿阴极纵向优先发生的位置。在此基础上，提出了一种电荷转移优化阴极（CTOC），从概念上验证了电荷转移调节在均匀化纵向锂浓度方面的有效性。CTOC具有双层结构：靠近分离器的无碳层具有大尺寸阴极，可增强锂离子转移，同时降低电子传导；靠近集流器的含碳层可确保高效的电子传导，从而纵向串联调制空间离子和电子传递动力学。通过梯度离子和电子传导，实现离子和电子的分离但同步的转移途径，CTOC使纵向均匀的锂分布在整个阴极上。因此，CTOC表现出优异的循环性能，在2C循环2000次后仍保持82.7%的容量，耐久性比传统单层设计提高27.4%。这项工作建立了电极级电荷转移优化作为非均相反应控制的设计原则，为高性能assb提供了基本见解和实用策略。

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Longitudinal Spatial Charge Transfer Optimization in Composite Cathode Enables Ultra-Stable All-Solid-State Batteries

All-solid-state batteries (ASSBs) promise high energy density and inherent safety but face critical challenges in complex charge transfer process across the longitudinal cathode. Here, through multiphysics simulation, it is firstly revealed that charge transfer critically governs electrochemical reaction heterogeneity, dictating where reactions initiate preferentially along the lengthways of cathode. Building on this insight, a charge-transfer-optimized cathode (CTOC) is proposed to conceptually validate the effectiveness of charge-transfer regulation in homogenizing the longitudinal Li concentration. The CTOC features a double-layer architecture: a carbon-free layer with large-sized catholytes near separator to enhance Li-ion transfer while reduce electron conduction and a carbon-containing layer near current collector to ensure efficient electronic conductivity, thus tandem modulating the spatial ion and electron transfer dynamics longitudinally. Through graded ionic and electronic conduction to achieve decoupled but synchronized ion and electron transfer pathways, the CTOC enables longitudinally homogeneous Li distribution throughout the cathode. As a result, CTOC exhibits excellent cycling performance, retaining 82.7% capacity after 2000 cycles at 2C, a 27.4% durability improvement over conventional single-layer designs. This work establishes electrode-level charge transfer optimization as a design principle for heterogeneous reaction control, offering fundamental insights and practical strategies for high-performance ASSBs.

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来源期刊

Energy & Environmental Science 化学-工程：化工

CiteScore

50.50

自引率

2.20%

发文量

349

审稿时长

2.2 months

期刊介绍： Energy & Environmental Science, a peer-reviewed scientific journal, publishes original research and review articles covering interdisciplinary topics in the (bio)chemical and (bio)physical sciences, as well as chemical engineering disciplines. Published monthly by the Royal Society of Chemistry (RSC), a not-for-profit publisher, Energy & Environmental Science is recognized as a leading journal. It boasts an impressive impact factor of 8.500 as of 2009, ranking 8th among 140 journals in the category "Chemistry, Multidisciplinary," second among 71 journals in "Energy & Fuels," second among 128 journals in "Engineering, Chemical," and first among 181 scientific journals in "Environmental Sciences." Energy & Environmental Science publishes various types of articles, including Research Papers (original scientific work), Review Articles, Perspectives, and Minireviews (feature review-type articles of broad interest), Communications (original scientific work of an urgent nature), Opinions (personal, often speculative viewpoints or hypotheses on current topics), and Analysis Articles (in-depth examination of energy-related issues).