Nature Communications (Dec 2023)

Enhanced formation of methane hydrate from active ice with high gas uptake

  • Peng Xiao,
  • Juan-Juan Li,
  • Wan Chen,
  • Wei-Xin Pang,
  • Xiao-Wan Peng,
  • Yan Xie,
  • Xiao-Hui Wang,
  • Chun Deng,
  • Chang-Yu Sun,
  • Bei Liu,
  • Yu-Jie Zhu,
  • Yun-Lei Peng,
  • Praveen Linga,
  • Guang-Jin Chen

DOI
https://doi.org/10.1038/s41467-023-43487-6
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 8

Abstract

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Abstract Gas hydrates provide alternative solutions for gas storage & transportation and gas separation. However, slow formation rate of clathrate hydrate has hindered their commercial development. Here we report a form of porous ice containing an unfrozen solution layer of sodium dodecyl sulfate, here named active ice, which can significantly accelerate gas hydrate formation while generating little heat. It can be readily produced via forming gas hydrates with water containing very low dosage (0.06 wt% or 600 ppm) of surfactant like sodium dodecyl sulfate and dissociating it below the ice point, or by simply mixing ice powder or natural snow with the surfactant. We prove that the active ice can rapidly store gas with high storage capacity up to 185 V g V w −1 with heat release of ~18 kJ mol−1 CH4 and the active ice can be easily regenerated by depressurization below the ice point. The active ice undergoes cyclic ice−hydrate−ice phase changes during gas uptake/release, thus removing most critical drawbacks of hydrate-based technologies. Our work provides a green and economic approach to gas storage and gas separation and paves the way to industrial application of hydrate-based technologies.