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Porous Calcium-Silicate-Hydrate as a Low-Cost Nano-Platform for Ultra-High CO 2 Capture and Storage.

Min LiuYuxi CaiQi LiuXue-Ting JinCheng XueShu-Xin ZhangPan FengYang-Hui Luo
Published in: Small methods (2023)
CO 2 capture and storage have been regarded as promising concepts to reduce anthropogenic CO 2 emissions. However, the high cost, inferior adsorption capacity, and higher effective activation temperature of traditional sorbents limit their practical application in efficient CO 2 capture. Here, a C-S-H@ZIF-8 (C-S-Z) sorbent is fabricated by in situ growth of the ZIF-8 shell on the C-S-H (calcium-silicate-hydrate) surface for ultra-high CO 2 adsorption and storage. Among the C-S-Z, the outer ZIF-8 shell acts as a transport channel that promotes CO 2 absorption toward the underlying C-S-H substrate for accelerated carbonation while preventing nitrogen and water from reaching the interior C-S-H. As a consequence, C-S-Z possesses the merits of ample pyrrolic nitrogen, porous structure, and ultra-high surface area (577.18 m 2  g -1 ), that contribute to an ultra-high CO 2 capture capacity, reaching 293.6 mg g -1 . DFT calculations show a high CO 2 adsorption energy and the mineral carbonation is dominant by the adsorption process. In particular, the advantages of the outstanding adsorption capacity, low cost, and high CO 2 selectivity make this C-S-H-based sorbent hold great potential in the practical application for direct air CO 2 capture and storage.
Keyphrases
  • low cost
  • high resolution
  • metal organic framework
  • risk assessment
  • high throughput
  • molecular dynamics simulations
  • mass spectrometry
  • climate change
  • gas chromatography