Ferrocyanide “Skin”-Mediated Anticatalysis: Mitigating Self-Discharge in Aqueous Electrochemical Devices

Ferrocyanide “Skin”-Mediated Anticatalysis: Mitigating Self-Discharge in Aqueous Electrochemical Devices

The interest in aqueous energy storage devices is surging due to their exceptional safety profile. However, in aqueous energy storage systems, interfacial side reactions, predominantly attributed to the oxygen evolution reaction (OER), result in significant self-discharge, which is concomitant with...

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محفوظ في:
التفاصيل البيبلوغرافية
المؤلف الرئيسي: Jin Li (119007) (author)
مؤلفون آخرون: Shuo Sun (626584) (author), Hao Huang (111923) (author), Teng Zhai (1459396) (author), Yanchen Liu (3691888) (author), Minghui Gu (803521) (author), Hongye Yang (11624399) (author), Mingqing Sun (18843015) (author), Tianyi Kou (1530160) (author), Shuang Li (146392) (author), Hui Xia (133168) (author)
منشور في: 2025
الموضوعات:
Medicine
Immunology
Infectious Diseases
Space Science
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
undesired phase transition
transition metal compounds
reaction pathway presents
oxygen evolution reaction
interfacial side reactions
exceptional safety profile
broadly applicable paradigm
aqueous electrochemical devices
significant energy barrier
fully charged electrode
oh )< sub
nickel cobalt oxide
2 </ sub
remarkable voltage retention
oer ), result
significant self
modified electrode
vanadium oxide
manganese oxide
tmc materials
taking nio
surging due
predominantly attributed
n –
mitigating self
idling within
idling process
hydroxyl ions
findings highlight
effectively shielding
bonding process
active sites
1 week
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الوصف
الملخص:The interest in aqueous energy storage devices is surging due to their exceptional safety profile. However, in aqueous energy storage systems, interfacial side reactions, predominantly attributed to the oxygen evolution reaction (OER), result in significant self-discharge, which is concomitant with the deterioration of both voltage and capacity. Herein, we propose the construction of a ferrocyanide “skin” on transition metal compounds (TMCs) to mitigate this issue. This engineered “skin” creates Fe–CN terminations, initiating a new reaction pathway featured by the bonding process of N–O and N–H bonds. This reaction pathway presents a significant energy barrier, effectively shielding the active sites for the OER from H<sub>2</sub>O molecules and hydroxyl ions. Taking NiO as an example, the ferrocyanide “skin” effectively suppresses the undesired phase transition from NiOOH to Ni(OH)<sub>2</sub> during the idling process of a fully charged electrode, enabling the as-modified electrode to achieve a remarkable voltage retention of 80.0% after 1 week of idling within a device. Furthermore, this concept demonstrates extensive applicability, extending to a range of TMC materials, including but not limited to manganese oxide, vanadium oxide, and nickel cobalt oxide. These findings highlight the efficacy of the ferrocyanide “skin” design strategy as a broadly applicable paradigm for suppressing H<sub>2</sub>O-induced undesirable phase transitions in aqueous energy storage devices.

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