Analyzing and Improving Conductive Networks in Commercial High-Energy Ni-rich Cathodes

IF 5.1 4区材料科学 Q2 ELECTROCHEMISTRY Batteries & Supercaps Pub Date : 2024-09-23 DOI:10.1002/batt.202400503

Adrian Lindner, Svenja Both, Dr.-Ing. Wolfgang Menesklou, Dr. Simon Hein, Dr. Timo Danner, Prof. Dr. Arnulf Latz, Prof. Dr.-Ing. Ulrike Krewer

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Abstract

Nickel-rich stoichiometries such as NMC811 have gained increasing relevance for lithium-ion-batteries in recent years due to their high specific capacity and reduced use of critical resources. However, low intrinsic electronic conductivity of NMC active materials makes the use of carbon-based additives necessary. Volume fraction and distribution of the carbon-binder-domain (CBD) have a significant impact on the electrode performance. This work combines high-resolution tomography and microstructure-resolved simulations to characterize the three-dimensional transport networks of a commercial NMC811 cathode. FIB-SEM tomography reveals that low CBD volume fractions with suboptimal distribution cause a non-percolating conductive network in the microstructure and thus unfavourably low electronic conductivity. Increasing the CBD content through virtual electrode design enables percolation and enhances electronic conductivity fundamentally. Simulations on both the real and virtually designed structures demonstrate how percolating CBD networks lead to a significantly improved energy density.

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商用高能富镍阴极导电网络的分析与改进

近年来，NMC811等富镍化学计量学由于其高比容量和减少关键资源的使用而与锂离子电池的相关性越来越大。然而，NMC活性材料的低本征电子导电性使得碳基添加剂的使用成为必要。碳结合物结构域（CBD）的体积分数和分布对电极性能有重要影响。这项工作结合了高分辨率断层扫描和微结构分辨率模拟来表征商用NMC811阴极的三维传输网络。FIB-SEM断层扫描显示，低CBD体积分数与次优分布导致微观结构中的非渗透导电网络，从而导致不利的低电子导电性。通过虚拟电极设计提高CBD含量，从根本上实现了渗透，提高了电子导电性。对真实和虚拟设计结构的模拟表明，渗透CBD网络如何显著提高能量密度。

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来源期刊

Batteries & Supercaps Multiple-

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.