催化作用
材料科学
溶解
吸附
阴极
多硫化物
化学工程
异核分子
锚固
动力学
纳米技术
活动中心
合理设计
联轴节(管道)
硫黄
纳米颗粒
无机化学
催化循环
密度泛函理论
相间
储能
化学动力学
作者
Xinpeng Gao,Ying Han,Gao Y,Liangnou Yang,Qibo Yu,Fengping Xiao,Lei Zhang,Peng Hu
摘要
ABSTRACT Room‐temperature sodium‐sulfur (RT Na–S) batteries have garnered considerable interest due to their low cost and high energy density. However, their practical application is impeded by the dissolution and shuttle effect of sodium polysulfides. In this work, we design a novel Zn‐Cu dual‐atom catalyst supported on g‐C 3 N 4 , which demonstrates superior catalytic activity and anchoring capability of the sulfur cathode through modulation of the electronic structure and adsorption configuration at the active sites. The catalyst is constructed by first fabricating single‐atom Zn sites, followed by the reduction and anchoring of adjacent Cu atoms via photogenerated electrons, leading to the formation of stable heteronuclear Zn‐Cu dual‐atom sites. Theoretical simulations reveal that the introduction of Cu induces notable splitting of the Zn d‐orbitals, upshifts the d‐band center, and strengthens coupling with the p‐orbitals of polysulfides. Moreover, the dual‐atom site offers multiple adsorption geometries, synergistically promoting both chemical anchoring and conversion kinetics of polysulfides. Therefore, the designed ZnCu dual‐atom‐based cathode exhibits long cycle stability and rate capability. This study provides new perspectives for the rational design of dual‐atom catalysts to suppress shuttle effects and accelerate reaction kinetics in RT Na–S batteries.
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