Nature Communications (Dec 2023)

Single-crystal ZrCo nanoparticle for advanced hydrogen and H-isotope storage

  • Zhenyang Li,
  • Shiyuan Liu,
  • Yanhui Pu,
  • Gang Huang,
  • Yingbo Yuan,
  • Ruiqi Zhu,
  • Xufeng Li,
  • Chunyan Chen,
  • Gao Deng,
  • Haihan Zou,
  • Peng Yi,
  • Ming Fang,
  • Xin Sun,
  • Junzhe He,
  • He Cai,
  • Jiaxiang Shang,
  • Xiaofang Liu,
  • Ronghai Yu,
  • Jianglan Shui

DOI
https://doi.org/10.1038/s41467-023-43828-5
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 10

Abstract

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Abstract Hydrogen-isotope storage materials are essential for the controlled nuclear fusion. However, the currently used smelting-ZrCo alloy suffers from rapid degradation of performance due to severe disproportionation. Here, we reveal a defect-derived disproportionation mechanism and report a nano-single-crystal strategy to solve ZrCo’s problems. Single-crystal nano-ZrCo is synthesized by a wet-chemistry method and exhibits excellent comprehensive hydrogen-isotope storage performances, including ultrafast uptake/release kinetics, high anti-disproportionation ability, and stable cycling, far superior to conventional smelting-ZrCo. Especially, a further incorporation of Ti into nano-ZrCo can almost suppress the disproportionation reaction. Moreover, a mathematical relationship between dehydrogenation temperature and ZrCo particle size is established. Additionally, a microwave method capable of nondestructively detecting the hydrogen storage state of ZrCo is developed. The proposed disproportionation mechanism and anti-disproportionation strategy will be instructive for other materials with similar problems.