Abstract

Hydrogen, the key element for solving the major environmental issues, exhibits rapid diffusion and localization in lattice defects of metals, which leads to embrittlement. However, the microstructure-hydrogen interactions in metallic materials are poorly understood. Therefore, a technique for capturing the microstructure-dependent hydrogen diffusion in real-time has long been targeted by researchers. Here, we successfully visualized the preferential hydrogen diffusion at grain boundaries (GBs) of pure Ni using a hydrogen video imaging system. A thin polyaniline layer was utilized as a hydrogenochromic sensor, and the hydrogen distribution was analyzed based on the color distribution of polyaniline. The system revealed the misorientation-dependent hydrogen flux at GBs of pure polycrystalline Ni with a micrometer-scale spatial resolution. It suggests that the geometrical structure of the GBs is a critical factor for preferential hydrogen diffusion. The use of the hydrogen video imaging system further advances the mechanistic understanding of hydrogen-material atomic interactions in polycrystalline metals and critically facilitates the development of hydrogen-related materials.

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