Nature Communications (Jan 2024)

Experimentally validated design principles of heteroatom-doped-graphene-supported calcium single-atom materials for non-dissociative chemisorption solid-state hydrogen storage

  • Yong Gao,
  • Zhenglong Li,
  • Pan Wang,
  • Wen-Gang Cui,
  • Xiaowei Wang,
  • Yaxiong Yang,
  • Fan Gao,
  • Mingchang Zhang,
  • Jiantuo Gan,
  • Chenchen Li,
  • Yanxia Liu,
  • Xinqiang Wang,
  • Fulai Qi,
  • Jing Zhang,
  • Xiao Han,
  • Wubin Du,
  • Jian Chen,
  • Zhenhai Xia,
  • Hongge Pan

DOI
https://doi.org/10.1038/s41467-024-45082-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 14

Abstract

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Abstract Non-dissociative chemisorption solid-state storage of hydrogen molecules in host materials is promising to achieve both high hydrogen capacity and uptake rate, but there is the lack of non-dissociative hydrogen storage theories that can guide the rational design of the materials. Herein, we establish generalized design principle to design such materials via the first-principles calculations, theoretical analysis and focused experimental verifications of a series of heteroatom-doped-graphene-supported Ca single-atom carbon nanomaterials as efficient non-dissociative solid-state hydrogen storage materials. An intrinsic descriptor has been proposed to correlate the inherent properties of dopants with the hydrogen storage capability of the carbon-based host materials. The generalized design principle and the intrinsic descriptor have the predictive ability to screen out the best dual-doped-graphene-supported Ca single-atom hydrogen storage materials. The dual-doped materials have much higher hydrogen storage capability than the sole-doped ones, and exceed the current best carbon-based hydrogen storage materials.