材料科学
涂层
阴极
氧化物
化学工程
碳纤维
保形涂层
电极
相容性(地球化学)
电导率
降级(电信)
图层(电子)
纳米技术
氧化还原
复合材料
极化(电化学)
电催化剂
兴奋剂
电化学
复合数
聚合物
炭黑
金属
作者
Weiyi Lin,Yifan Wu,Xincan Cai,Rongliang Shang,Yingdong Deng,Yixiao Liu,Qing Zhang,Jin Xie
标识
DOI:10.1021/acsaem.5c03496
摘要
Nickel-rich layered oxide cathodes (NCMs) face critical challenges, including structural degradation and inadequate rate capability, limiting their application in high-energy lithium-ion batteries. Although carbon coating is a promising strategy to concurrently enhance electronic conductivity and interfacial stability for many different types of electrode materials, conventional coating approaches suffer from detrimental interfacial reactions between carbon precursors and NCMs. Here, we systematically investigate the reaction behavior between NCMs and carbon sources and propose a gradient doping and carbon coating hybrid surface architecture. We found that a conformal ZnO interlayer deposited by ALD, which subsequently undergoes partial transformation into a Zn2+ gradient-doped layer during postannealing, effectively suppresses deleterious interfacial reactions between NCMs and carbon precursors. The modified cathode (CZ-NCM) achieves exceptional capacity retention (99.6% after 100 cycles) and superior rate capability (166.3 mAh/g at 5C). This work presents a practical strategy to minimize detrimental interfacial reactions between a reductive carbon precursor and an oxidative oxide cathode, providing a promising avenue to construct multifunctional interfaces for high-voltage cathodes.
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