Universal Single Atom Engineering Enhances Coulombic Efficiency of Ion Storage in Carbon Materials DOI Open Access
Tiantian Wang, Xuliang Deng, Wei Shao

и другие.

Small, Год журнала: 2025, Номер unknown

Опубликована: Март 27, 2025

Metal single atoms are widely used to optimize the microstructure of carbon materials improve their ion storage capacity and rate performance, but impact on another key parameter, Coulombic efficiency (CE), is not sufficiently addressed confirmed. Herein, a universal phenomenon reported that carbon-loaded asymmetric sulfur-modified metal-N4 moiety (MN4-S, M = Zn, Fe, Cu, Ni) possesses higher CE than symmetric MN4 moiety, this applicable various matrices, ions (Li+, Na+, K+), charge discharge rates, electrolyte formulations. The MN4-S exhibits larger CEs (0.03-0.46% average CEs, 4.2-28.4% initial CEs) smaller variance compared implying better reversible stability. mechanism driving revealed by ZnN4-S sodium process. coordination promotes rapid diffusion kinetics changing density. Meanwhile, can reduce adsorption energy regulate surface chemical reactivity material increase reversibility storage, thereby achieving

Язык: Английский

Universal Single Atom Engineering Enhances Coulombic Efficiency of Ion Storage in Carbon Materials DOI Open Access
Tiantian Wang, Xuliang Deng, Wei Shao

и другие.

Small, Год журнала: 2025, Номер unknown

Опубликована: Март 27, 2025

Metal single atoms are widely used to optimize the microstructure of carbon materials improve their ion storage capacity and rate performance, but impact on another key parameter, Coulombic efficiency (CE), is not sufficiently addressed confirmed. Herein, a universal phenomenon reported that carbon-loaded asymmetric sulfur-modified metal-N4 moiety (MN4-S, M = Zn, Fe, Cu, Ni) possesses higher CE than symmetric MN4 moiety, this applicable various matrices, ions (Li+, Na+, K+), charge discharge rates, electrolyte formulations. The MN4-S exhibits larger CEs (0.03-0.46% average CEs, 4.2-28.4% initial CEs) smaller variance compared implying better reversible stability. mechanism driving revealed by ZnN4-S sodium process. coordination promotes rapid diffusion kinetics changing density. Meanwhile, can reduce adsorption energy regulate surface chemical reactivity material increase reversibility storage, thereby achieving

Язык: Английский

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