Quest for an Optimal Methane Hydrate Formation in the Pores of Hydrolytically Stable Metal-Organic Frameworks

Carlos Cuadrado-Collados; Georges Mouchaham; Luke Daemen; Yongqiang Cheng; Anibal Ramirez-Cuesta; Himanshu Aggarwal; Alexander Missyul; Mohamed Eddaoudi; Youssef Belmabkhout; Joaquin Silvestre-Albero

doi:10.1021/jacs.0c01459

Quest for an Optimal Methane Hydrate Formation in the Pores of Hydrolytically Stable Metal-Organic Frameworks

Carlos Cuadrado-Collados, Georges Mouchaham, Luke Daemen, Yongqiang Cheng, Anibal Ramirez-Cuesta, Himanshu Aggarwal, Alexander Missyul, Mohamed Eddaoudi, Youssef Belmabkhout, Joaquin Silvestre-Albero

Research output: Contribution to journal › Article › peer-review

75 Scopus citations

Abstract

Porous metal-organic frameworks (MOFs) capable of storing a relatively high amount of dry methane (CH4) in the adsorbed phase are largely explored; however, solid CH4 storage in confined pores of MOFs in the form of hydrates is yet to be discovered. Here we report a rational approach to form CH4 hydrates by taking advantage of the optimal pore confinement in relatively narrow cavities of hydrolytically stable MOFs. Unprecedentedly, we were able to isolate methane hydrate (MH) nanocrystals with an sI structure encapsulated inside MOF pores with an optimal cavity dimension. It was found that confined nanocrystals require cavities slightly larger than the unit cell crystal size of MHs (1.2 nm), as exemplified in the experimental case study performed on Cr-soc-MOF-1 vs smaller cavities of Y-shp-MOF-5. Under these conditions, the excess amount of methane stored in the pores of Cr-soc-MOF-1 in the form of MH was found to be ≈50% larger than the corresponding dry adsorbed amount at 10 MPa. More importantly, the pressure gradient driving the CH4 storage/delivery process could be drastically reduced compared to the conventional CH4-adsorbed phase storage on the dry Cr-soc-MOF-1 (≤3 MPa vs 10 MPa).

Original language	English
Pages (from-to)	13391-13397
Number of pages	7
Journal	Journal of the American Chemical Society
Volume	142
Issue number	31
DOIs	https://doi.org/10.1021/jacs.0c01459
State	Published - Aug 5 2020

Funding

G.M., M.E., and Y.B. thank the Aramco sponsored research fund (contract. 66600024505). We would like also to acknowledge the support by King Abdullah University of Science and Technology. J.S.A. would like to acknowledge financial support from the MINECO (MAT2016-80285-p), Generalitat Valenciana (PROMETEOII/2014/004), Oak Ridge beam time availability (Project IPTS-20859.1), and Spanish ALBA synchrotron (Project 2020014008). INS experiments were conducted at the VISION beamline (IPTS-20859) at the Spallation Neutron Source, Oak Ridge National Laboratory (ORNL), which is supported by the Scientific User Facilities Division, Office of Basic Energy Sciences (BES), U.S. Department of Energy (DOE), under contract no. DE-AC0500OR22725 with UT Battelle, LLC. The computing resources were made available through the VirtuES and the ICE-MAN projects, funded by the Laboratory Directed Research and Development programme and by Compute and Data Environment for Science (CADES) at ORNL.

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10.1021/jacs.0c01459

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Cuadrado-Collados, C., Mouchaham, G., Daemen, L., Cheng, Y., Ramirez-Cuesta, A., Aggarwal, H., Missyul, A., Eddaoudi, M., Belmabkhout, Y., & Silvestre-Albero, J. (2020). Quest for an Optimal Methane Hydrate Formation in the Pores of Hydrolytically Stable Metal-Organic Frameworks. Journal of the American Chemical Society, 142(31), 13391-13397. https://doi.org/10.1021/jacs.0c01459

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abstract = "Porous metal-organic frameworks (MOFs) capable of storing a relatively high amount of dry methane (CH4) in the adsorbed phase are largely explored; however, solid CH4 storage in confined pores of MOFs in the form of hydrates is yet to be discovered. Here we report a rational approach to form CH4 hydrates by taking advantage of the optimal pore confinement in relatively narrow cavities of hydrolytically stable MOFs. Unprecedentedly, we were able to isolate methane hydrate (MH) nanocrystals with an sI structure encapsulated inside MOF pores with an optimal cavity dimension. It was found that confined nanocrystals require cavities slightly larger than the unit cell crystal size of MHs (1.2 nm), as exemplified in the experimental case study performed on Cr-soc-MOF-1 vs smaller cavities of Y-shp-MOF-5. Under these conditions, the excess amount of methane stored in the pores of Cr-soc-MOF-1 in the form of MH was found to be ≈50% larger than the corresponding dry adsorbed amount at 10 MPa. More importantly, the pressure gradient driving the CH4 storage/delivery process could be drastically reduced compared to the conventional CH4-adsorbed phase storage on the dry Cr-soc-MOF-1 (≤3 MPa vs 10 MPa).",

author = "Carlos Cuadrado-Collados and Georges Mouchaham and Luke Daemen and Yongqiang Cheng and Anibal Ramirez-Cuesta and Himanshu Aggarwal and Alexander Missyul and Mohamed Eddaoudi and Youssef Belmabkhout and Joaquin Silvestre-Albero",

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Cuadrado-Collados, C, Mouchaham, G, Daemen, L, Cheng, Y , Ramirez-Cuesta, A, Aggarwal, H, Missyul, A, Eddaoudi, M, Belmabkhout, Y & Silvestre-Albero, J 2020, 'Quest for an Optimal Methane Hydrate Formation in the Pores of Hydrolytically Stable Metal-Organic Frameworks', Journal of the American Chemical Society, vol. 142, no. 31, pp. 13391-13397. https://doi.org/10.1021/jacs.0c01459

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T1 - Quest for an Optimal Methane Hydrate Formation in the Pores of Hydrolytically Stable Metal-Organic Frameworks

AU - Cuadrado-Collados, Carlos

AU - Mouchaham, Georges

AU - Daemen, Luke

AU - Cheng, Yongqiang

AU - Ramirez-Cuesta, Anibal

AU - Aggarwal, Himanshu

AU - Missyul, Alexander

AU - Eddaoudi, Mohamed

AU - Belmabkhout, Youssef

AU - Silvestre-Albero, Joaquin

PY - 2020/8/5

Y1 - 2020/8/5

N2 - Porous metal-organic frameworks (MOFs) capable of storing a relatively high amount of dry methane (CH4) in the adsorbed phase are largely explored; however, solid CH4 storage in confined pores of MOFs in the form of hydrates is yet to be discovered. Here we report a rational approach to form CH4 hydrates by taking advantage of the optimal pore confinement in relatively narrow cavities of hydrolytically stable MOFs. Unprecedentedly, we were able to isolate methane hydrate (MH) nanocrystals with an sI structure encapsulated inside MOF pores with an optimal cavity dimension. It was found that confined nanocrystals require cavities slightly larger than the unit cell crystal size of MHs (1.2 nm), as exemplified in the experimental case study performed on Cr-soc-MOF-1 vs smaller cavities of Y-shp-MOF-5. Under these conditions, the excess amount of methane stored in the pores of Cr-soc-MOF-1 in the form of MH was found to be ≈50% larger than the corresponding dry adsorbed amount at 10 MPa. More importantly, the pressure gradient driving the CH4 storage/delivery process could be drastically reduced compared to the conventional CH4-adsorbed phase storage on the dry Cr-soc-MOF-1 (≤3 MPa vs 10 MPa).

AB - Porous metal-organic frameworks (MOFs) capable of storing a relatively high amount of dry methane (CH4) in the adsorbed phase are largely explored; however, solid CH4 storage in confined pores of MOFs in the form of hydrates is yet to be discovered. Here we report a rational approach to form CH4 hydrates by taking advantage of the optimal pore confinement in relatively narrow cavities of hydrolytically stable MOFs. Unprecedentedly, we were able to isolate methane hydrate (MH) nanocrystals with an sI structure encapsulated inside MOF pores with an optimal cavity dimension. It was found that confined nanocrystals require cavities slightly larger than the unit cell crystal size of MHs (1.2 nm), as exemplified in the experimental case study performed on Cr-soc-MOF-1 vs smaller cavities of Y-shp-MOF-5. Under these conditions, the excess amount of methane stored in the pores of Cr-soc-MOF-1 in the form of MH was found to be ≈50% larger than the corresponding dry adsorbed amount at 10 MPa. More importantly, the pressure gradient driving the CH4 storage/delivery process could be drastically reduced compared to the conventional CH4-adsorbed phase storage on the dry Cr-soc-MOF-1 (≤3 MPa vs 10 MPa).

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ER -

Quest for an Optimal Methane Hydrate Formation in the Pores of Hydrolytically Stable Metal-Organic Frameworks

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