Organic electrode materials are promising candidates for battery elec-trode materials due to the abundant resource,structural diversity,envi-ronmental friendliness,and potential low cost.[1]However,most of reported organic materials rely on one-electron redox reaction per active group.[2]For example,carbonyl group(C=O)transforms into C-O-Li by accepting one electron.This severely limits the specific capacities and energy densities,which are much lower than their inor-ganic counterparts for primary lithium batteries,such as CFx,SO2,SOCl2,and SF6.Therefore,new organic electrode materials that enable multi-electron reaction per active group need to be developed to meet the demand of high energy density.

Zhaoyang Chen;Yan Yao

Department of Electrical and Computer Engineering and Texas Center for Superconductivity,University of Houston,Houston,TX,USA

能源与环境材料（英文）

[1]Zhaoyang Chen;Yan Yao-.Ultrahigh Energy Density Li-Organic Primary Batteries)[J].能源与环境材料（英文）,2022(04):1010-1011

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