Decoupling the air sensitivity of Na-layered oxides

Yang Yang(Chinese Academy of Sciences), Zaifa Wang(Yanshan University), Congcong Du(Yanshan University), Daniel Kuok Ho Tang(Chinese Academy of Sciences), Xinyan Li(Chinese Academy of Sciences), Siyuan Wu(Chinese Academy of Sciences), Xiaowei Li(Chinese Academy of Sciences), Xiao Zhang(Chinese Academy of Sciences), Xubin Wang(Chinese Academy of Sciences), Yaoshen Niu(Chinese Academy of Sciences), Feixiang Ding(Chinese Academy of Sciences), Xiaohui Rong(Yangtze River Delta Physics Research Center (China)), Yaxiang Lu(Chinese Academy of Sciences), Nian Zhang(Shanghai Institute of Microsystem and Information Technology), Juping Xu(China Spallation Neutron Source), Ruijuan Xiao(Chinese Academy of Sciences), Qinghua Zhang(Chinese Academy of Sciences), Xuefeng Wang(Chinese Academy of Sciences), Wen Yin(China Spallation Neutron Source), Junmei Zhao(Institute of Process Engineering), Liquan Chen(Chinese Academy of Sciences), Jianyu Huang(Yanshan University), Yong‐Sheng Hu(Chinese Academy of Sciences)
Science
August 15, 2024
10.1126/science.adm9223
Cited by 226

Abstract

Air sensitivity remains a substantial barrier to the commercialization of sodium (Na)-layered oxides (NLOs). This problem has puzzled the community for decades because of the complexity of interactions between air components and their impact on both bulk and surfaces of NLOs. We show here that water vapor plays a pivotal role in initiating destructive acid and oxidative degradations of NLOs only when coupled with carbon dioxide or oxygen, respectively. Quantification analysis revealed that reducing the defined cation competition coefficient (η), which integrates the effects of ionic potential and sodium content, and increasing the particle size can enhance the resistance to acid attack, whereas using high-potential redox couples can eliminate oxidative degradation. These findings elucidate the underlying air deterioration mechanisms and rationalize the design of air-stable NLOs.

Related Papers

Research Development on Sodium-Ion Batteries
Naoaki Yabuuchi, Kei Kubota, Mouad Dahbi et al.|Chemical Reviews|2014|6.3k
Humidity fixed points of binary saturated aqueous solutions
Lewis Greenspan|Journal of Research of the National Bureau of Standards Section A Physics and Chemistry|1977|3.9k
Electrode Materials for Rechargeable Sodium‐Ion Batteries: Potential Alternatives to Current Lithium‐Ion Batteries
Sung‐Wook Kim, Dong‐Hwa Seo, Xiaohua Ma et al.|Advanced Energy Materials|2012|3.3k
Proton Conductivity:  Materials and Applications
Klaus‐Dieter Kreuer|Chemistry of Materials|1996|2.5k
Quantifying inactive lithium in lithium metal batteries
Chengcheng Fang, Jinxing Li, Minghao Zhang et al.|Nature|2019|1.4k