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Structure I methane hydrate confined in C8-grafted SBA-15: A highly efficient storage system enabling ultrafast methane loading and unloading

Author

Listed:
  • Beckwée, Emile Jules
  • Houlleberghs, Maarten
  • Ciocarlan, Radu-George
  • Chandran, C. Vinod
  • Radhakrishnan, Sambhu
  • Hanssens, Lucas
  • Cool, Pegie
  • Martens, Johan
  • Breynaert, Eric
  • Baron, Gino V.
  • Denayer, Joeri F.M.

Abstract

Confinement of water and methane in mesopores of hydrophobized SBA-15 is demonstrated to promote methane hydrate formation. In comparison to as-synthesized SBA-15, hydrophobization by C8 grafting accelerates the kinetics of methane storage in and delivery from the hydrate. C8 grafting density was determined at 0.5 groups nm−2 based on TGA and quantitative NMR spectroscopy. Multinuclear 1H-1H DQSQ and 1H-1H RFDR NMR provided spectroscopic evidence for the occurrence of C8 chains inside the mesopores of SBA-15, by showcasing close spatial proximity between the grafted C8 chains and pore-intruded water species. X-ray diffraction demonstrates formation of Structure I hydrate on SBA-15 C8. At 7.0 MPa and 248 K, the water-to-hydrate conversion on hydrophobized SBA-15 C8 reaches 96% as compared to only 71% on a pristine SBA-15 sample with comparable pore size, pore volume and surface area. The clathrate loading amounted to 14.8 g/g. 2D correlation NMR spectroscopy (1H-13C CP-HETCOR, 1H-1H RFDR) reveals hydrate formation occurs within pores of SBA-15 C8 as well as in interparticle volumes. Following the initial crystallization of SBA-15 C8-supported methane hydrate taking several hours, a pressure swing process at 248 K allows to desorb and re-adsorb methane from the structure within minutes and without thawing the frozen water structure. Fast loading and unloading of methane was achieved in 19 subsequent cycles without losses in kinetics. The ability to harvest the gas and regenerate the structure without the need to re-freeze the water represents a 50% energy gain with respect to melting and subsequently recrystallizing the hydrate at 298 K and 248 K, respectively. After methane desorption, a small amount of residual methane hydrate in combination with an amorphous yet locally ordered ice phase is observed using 13C and 2H NMR spectroscopy. This effect offers an explanation for the enhanced hydrate formation kinetics in adsorption-desorption cycles. These findings open new perspectives for clathrate hydrate-based methane storage.

Suggested Citation

  • Beckwée, Emile Jules & Houlleberghs, Maarten & Ciocarlan, Radu-George & Chandran, C. Vinod & Radhakrishnan, Sambhu & Hanssens, Lucas & Cool, Pegie & Martens, Johan & Breynaert, Eric & Baron, Gino V. &, 2024. "Structure I methane hydrate confined in C8-grafted SBA-15: A highly efficient storage system enabling ultrafast methane loading and unloading," Applied Energy, Elsevier, vol. 353(PA).
    • Handle: RePEc:eee:appene:v:353:y:2024:i:pa:s0306261923014848
    DOI: 10.1016/j.apenergy.2023.122120
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    1. Zhou, Xuebing & Kang, Zhanxiao & Lu, Jingsheng & Fan, Jintu & Zang, Xiaoya & Liang, Deqing, 2023. "Recyclable and efficient hydrate-based CH4 storage strengthened by fabrics," Applied Energy, Elsevier, vol. 336(C).
    2. Chong, Zheng Rong & Yang, She Hern Bryan & Babu, Ponnivalavan & Linga, Praveen & Li, Xiao-Sen, 2016. "Review of natural gas hydrates as an energy resource: Prospects and challenges," Applied Energy, Elsevier, vol. 162(C), pages 1633-1652.
    3. Li, Xiao-Yan & Feng, Jing-Chun & Li, Xiao-Sen & Wang, Yi & Hu, Heng-Qi, 2022. "Experimental study of methane hydrate formation and decomposition in the porous medium with different thermal conductivities and grain sizes," Applied Energy, Elsevier, vol. 305(C).
    4. Mirian E. Casco & Joaquín Silvestre-Albero & Anibal J. Ramírez-Cuesta & Fernando Rey & Jose L. Jordá & Atul Bansode & Atsushi Urakawa & Inma Peral & Manuel Martínez-Escandell & Katsumi Kaneko & Franci, 2015. "Methane hydrate formation in confined nanospace can surpass nature," Nature Communications, Nature, vol. 6(1), pages 1-8, May.
    5. Sina Eslami & Behnam Farhangdoost & Hamidreza Shahverdi & Mohsen Mohammadi, 2021. "Surface grafting of silica nanoparticles using 3‐aminopropyl (triethoxysilane) to improve the CO2 absorption and enhance the gas consumption during the CO2 hydrate formation," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 11(5), pages 939-953, October.
    6. Bhattacharjee, Gaurav & Prakash Veluswamy, Hari & Kumar, Rajnish & Linga, Praveen, 2020. "Rapid methane storage via sII hydrates at ambient temperature," Applied Energy, Elsevier, vol. 269(C).
    7. Xie, Yan & Zheng, Tao & Zhong, Jin-Rong & Zhu, Yu-Jie & Wang, Yun-Fei & Zhang, Yu & Li, Rui & Yuan, Qing & Sun, Chang-Yu & Chen, Guang-Jin, 2020. "Experimental research on self-preservation effect of methane hydrate in porous sediments," Applied Energy, Elsevier, vol. 268(C).
    8. Zhang, Ye & Bhattacharjee, Gaurav & Dharshini Vijayakumar, Mohana & Linga, Praveen, 2022. "Rapid and energy-dense methane hydrate formation at near ambient temperature using 1,3-dioxolane as a dual-function promoter," Applied Energy, Elsevier, vol. 311(C).
    9. Li, Bo & Zhang, Ting-Ting & Wan, Qing-Cui & Feng, Jing-Chun & Chen, Ling-Ling & Wei, Wen-Na, 2021. "Kinetic study of methane hydrate development involving the role of self-preservation effect in frozen sandy sediments," Applied Energy, Elsevier, vol. 300(C).
    10. Veluswamy, Hari Prakash & Kumar, Asheesh & Seo, Yutaek & Lee, Ju Dong & Linga, Praveen, 2018. "A review of solidified natural gas (SNG) technology for gas storage via clathrate hydrates," Applied Energy, Elsevier, vol. 216(C), pages 262-285.
    11. Zhang, Yu & Li, Xiao-Sen & Chen, Zhao-Yang & Xia, Zhi-Ming & Wang, Yi & Li, Gang, 2018. "Experimental and modeling study on controlling factor of methane hydrate formation in silica gels," Applied Energy, Elsevier, vol. 225(C), pages 827-834.
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