Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena
Marine sediments hosting gas hydrates are commonly fine-grained (silts, muds, clays) with very narrow mean pore diameters (0.1 mm). This has led to speculation that capillary phenomena could play an important role in controlling hydrate distribution in the seafloor, and may be in part responsible fo...
| Published in: | Geological Society, London, Special Publications |
|---|---|
| Main Authors: | , , |
| Format: | Article in Journal/Newspaper |
| Language: | English |
| Published: |
The Geological Society, London, Special Publications
2009
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| Subjects: | |
| Online Access: | https://kar.kent.ac.uk/23118/ https://doi.org/10.1144/SP319.12 |
| _version_ | 1829311369762045952 |
|---|---|
| author | Anderson, Ross A. Tohidi, Bahman Webber, J. Beau W. |
| author_facet | Anderson, Ross A. Tohidi, Bahman Webber, J. Beau W. |
| author_sort | Anderson, Ross A. |
| collection | University of Kent: KAR - Kent Academic Repository |
| container_issue | 1 |
| container_start_page | 145 |
| container_title | Geological Society, London, Special Publications |
| container_volume | 319 |
| description | Marine sediments hosting gas hydrates are commonly fine-grained (silts, muds, clays) with very narrow mean pore diameters (0.1 mm). This has led to speculation that capillary phenomena could play an important role in controlling hydrate distribution in the seafloor, and may be in part responsible for discrepancies between observed and predicted (from bulk phase equilibria) hydrate stability zone (HSZ) thicknesses. Numerous recent laboratory studies have confirmed a close relationship between hydrate inhibition and pore size, stability being reduced in narrow pores; however, to date the focus has been hydrate dissociation conditions in porous media, with capillary controls on the equally important process of hydrate growth being largely neglected. Here, we present experimental methane hydrate growth and dissociation conditions for synthetic mesoporous silicas over a range of pressure–temperature (PT) conditions (273– 293 K, to 20 MPa) and pore size distributions. Results demonstrate that hydrate formation and decomposition in narrow pore networks is characterized by a distinct hysteresis: solid growth occurs at significantly lower temperatures (or higher pressures) than dissociation. Hysteresis takes the form of repeatable, irreversible closed primary growth and dissociation PT loops, within which various characteristic secondary ‘scanning’ curve pathways may be followed. Similar behaviour has recently been observed for ice–water systems in porous media, and is characteristic of liquid–vapour transitions in mesoporous materials. The causes of such hysteresis are still not fully understood; our results suggest pore blocking during hydrate growth as a primary cause. |
| format | Article in Journal/Newspaper |
| genre | Methane hydrate |
| genre_facet | Methane hydrate |
| id | ftkentuniv:oai:kar.kent.ac.uk:23118 |
| institution | Open Polar |
| language | English |
| op_collection_id | ftkentuniv |
| op_container_end_page | 159 |
| op_doi | https://doi.org/10.1144/SP319.12 |
| op_relation | https://kar.kent.ac.uk/23118/1/2009_Ross_Geo-Soc_SP319_proof.pdf https://kar.kent.ac.uk/23118/4/2009_Ross_Geo-soc_paper_p1.pdf Anderson, Ross A., Tohidi, Bahman, Webber, J. Beau W. (2009) Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena. Sediment-Hosted Gas Hydrates: New Insights on Natural and Synthetic Systems., 319 . pp. 145-159. (doi:10.1144/SP319.12 <https://doi.org/10.1144/SP319.12>) (KAR id:23118 </23118>) |
| publishDate | 2009 |
| publisher | The Geological Society, London, Special Publications |
| record_format | openpolar |
| spelling | ftkentuniv:oai:kar.kent.ac.uk:23118 2025-04-13T14:22:39+00:00 Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena Anderson, Ross A. Tohidi, Bahman Webber, J. Beau W. 2009-09 application/pdf https://kar.kent.ac.uk/23118/ https://doi.org/10.1144/SP319.12 en eng The Geological Society, London, Special Publications https://kar.kent.ac.uk/23118/1/2009_Ross_Geo-Soc_SP319_proof.pdf https://kar.kent.ac.uk/23118/4/2009_Ross_Geo-soc_paper_p1.pdf Anderson, Ross A., Tohidi, Bahman, Webber, J. Beau W. (2009) Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena. Sediment-Hosted Gas Hydrates: New Insights on Natural and Synthetic Systems., 319 . pp. 145-159. (doi:10.1144/SP319.12 <https://doi.org/10.1144/SP319.12>) (KAR id:23118 </23118>) QC807 Geophysics (for Applied Geophysics see TN269) QE Geology QC176.8.N35 Nanoscience nanotechnology Article PeerReviewed 2009 ftkentuniv https://doi.org/10.1144/SP319.12 2025-03-19T05:15:32Z Marine sediments hosting gas hydrates are commonly fine-grained (silts, muds, clays) with very narrow mean pore diameters (0.1 mm). This has led to speculation that capillary phenomena could play an important role in controlling hydrate distribution in the seafloor, and may be in part responsible for discrepancies between observed and predicted (from bulk phase equilibria) hydrate stability zone (HSZ) thicknesses. Numerous recent laboratory studies have confirmed a close relationship between hydrate inhibition and pore size, stability being reduced in narrow pores; however, to date the focus has been hydrate dissociation conditions in porous media, with capillary controls on the equally important process of hydrate growth being largely neglected. Here, we present experimental methane hydrate growth and dissociation conditions for synthetic mesoporous silicas over a range of pressure–temperature (PT) conditions (273– 293 K, to 20 MPa) and pore size distributions. Results demonstrate that hydrate formation and decomposition in narrow pore networks is characterized by a distinct hysteresis: solid growth occurs at significantly lower temperatures (or higher pressures) than dissociation. Hysteresis takes the form of repeatable, irreversible closed primary growth and dissociation PT loops, within which various characteristic secondary ‘scanning’ curve pathways may be followed. Similar behaviour has recently been observed for ice–water systems in porous media, and is characteristic of liquid–vapour transitions in mesoporous materials. The causes of such hysteresis are still not fully understood; our results suggest pore blocking during hydrate growth as a primary cause. Article in Journal/Newspaper Methane hydrate University of Kent: KAR - Kent Academic Repository Geological Society, London, Special Publications 319 1 145 159 |
| spellingShingle | QC807 Geophysics (for Applied Geophysics see TN269) QE Geology QC176.8.N35 Nanoscience nanotechnology Anderson, Ross A. Tohidi, Bahman Webber, J. Beau W. Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| title | Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| title_full | Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| title_fullStr | Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| title_full_unstemmed | Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| title_short | Gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| title_sort | gas hydrate growth and dissociation in narrow pore networks: capillary inhibition and hysteresis phenomena |
| topic | QC807 Geophysics (for Applied Geophysics see TN269) QE Geology QC176.8.N35 Nanoscience nanotechnology |
| topic_facet | QC807 Geophysics (for Applied Geophysics see TN269) QE Geology QC176.8.N35 Nanoscience nanotechnology |
| url | https://kar.kent.ac.uk/23118/ https://doi.org/10.1144/SP319.12 |