In Situ Tracking of Water Oxidation Generated Nanoscale Dynamics in Layered Double Hydroxides Nanosheets.
Yuqing WangChao ChenXuya XiongSebastian Amland SkaanvikYuge ZhangEspen Drath Bo JesenZegao WangWei LiuMingdong DongPublished in: Journal of the American Chemical Society (2024)
Layered double hydroxides (LDHs) are potential catalysts for water oxidation, and it is recognized that they undergo dynamic evolution during the operation. However, little is known about the interfacial behaviors at the nanoscale under working conditions nor the underlying effects on electrocatalytic performance. Herein, using electrochemical atomic force microscopy, we in situ visualize the heterogeneous evolution of LDH nanosheets during oxygen evolution reaction (OER). By further combining density functional theory calculations, we elucidate the origin of the heterogeneous dynamics and their impact on the OER efficiency. Our findings demonstrate that NiCo LDHs transform to the catalytically active NiCoO x (OH) 2- x phase during OER, and the redox transition between is accompanied by compressive and tensile strain, leading to in-plane contraction and reversible expansion of the nanosheets. Nonisotropic strain and out-of-plane strain relaxation due to defects and interparticle interactions result in cracking and wrinkling in the nanostructure, which is responsible for the partial activation and long-term deterioration of LDH electrocatalysts toward the OER. With this knowledge, we suggest and validate that engineering defects can precisely tune these dynamic behaviors, improving the OER activity and stability among LDH-based electrocatalysts.
Keyphrases
- atomic force microscopy
- density functional theory
- reduced graphene oxide
- metal organic framework
- electron transfer
- single molecule
- high speed
- highly efficient
- molecular dynamics
- gold nanoparticles
- visible light
- quantum dots
- transition metal
- hydrogen peroxide
- ionic liquid
- healthcare
- molecular dynamics simulations
- high resolution
- nitric oxide
- molecularly imprinted
- simultaneous determination