Authors
Xi Wang, Long Pan, Jilong Xu, Xu Dong, ZhengMing Sun, Dawei Sha, Jianning Ding
Published in
Langmuir : the ACS journal of surfaces and colloids. Jul 05, 2026. Epub Jul 05, 2026.
Abstract
Aqueous zinc-ion batteries are promising for their inherent safety, low cost, and environmental friendliness. However, their performance is limited by dendrite growth, hydrogen evolution, and interfacial instability from uncontrolled Zn2+ deposition. Although graphitic carbon nitride (g-C3N4) has been explored as an artificial solid electrolyte interphase (ASEI), its limited active sites and sluggish Zn2+ transport restrict long-term stability. More importantly, the roles of different doping types in regulating interfacial Zn2+ behavior remain unclear. Herein, anion (O) and cation (K) are doped into g-C3N4 to construct model ASEI layers for elucidating their respective roles in interfacial regulation. Combined experimental characterizations and theoretical calculations reveal that cation doping (KCN) decreases Zn2+ diffusion barrier, thereby facilitating Zn2+ transport across the interphase. In contrast, anion doping (OCN) induces strong electrostatic interaction and enhances Zn2+ adsorption affinity, leading to improved zincophilicity and synergistically ion transport. These distinct interfacial interactions result in markedly different Zn deposition behaviors, where anion doping enables more uniform nucleation and suppressed dendrite growth. Consequently, the OCN@Zn anode exhibits enhanced cycling stability. This work clarifies the roles of anion and cation doping in regulating interfacial Zn2+ deposition from the perspectives of ion transport and interfacial nucleation, and provides mechanistic insights and design guidelines for constructing high-efficiency ASEI layers via heteroatom engineering.
PMID:
42402190
Bibliographic data and abstract were imported from PubMed on 06 Jul 2026.
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