Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties

We describe a new and efficient technique to grow aggregates of pure methane hydrate in quantities suitable for physical and material properties testing. Test specimens were grown under static conditions by combining cold, pressurized CH4 gas with granulated H2O ice, and then warming the reactants t...

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Published in:Energy & Fuels
Main Authors: Stern, Laura A., Kirby, Stephen H., Durham, William B.
Format: Article in Journal/Newspaper
Language:English
Published: American Chemical Society 1998
Subjects:
Methane hydrate
Online Access:https://oceanrep.geomar.de/id/eprint/42635/
https://oceanrep.geomar.de/id/eprint/42635/1/Stern,%20Kirby.pdf
https://doi.org/10.1021/ef970167m
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spelling ftoceanrep:oai:oceanrep.geomar.de:42635 2023-05-15T17:11:31+02:00 Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties Stern, Laura A. Kirby, Stephen H. Durham, William B. 1998 text https://oceanrep.geomar.de/id/eprint/42635/ https://oceanrep.geomar.de/id/eprint/42635/1/Stern,%20Kirby.pdf https://doi.org/10.1021/ef970167m en eng American Chemical Society https://oceanrep.geomar.de/id/eprint/42635/1/Stern,%20Kirby.pdf Stern, L. A., Kirby, S. H. and Durham, W. B. (1998) Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties. Energy & Fuels, 12 (2). pp. 201-211. DOI 10.1021/ef970167m <https://doi.org/10.1021/ef970167m>. doi:10.1021/ef970167m info:eu-repo/semantics/restrictedAccess Article PeerReviewed 1998 ftoceanrep https://doi.org/10.1021/ef970167m 2023-04-07T15:39:14Z We describe a new and efficient technique to grow aggregates of pure methane hydrate in quantities suitable for physical and material properties testing. Test specimens were grown under static conditions by combining cold, pressurized CH4 gas with granulated H2O ice, and then warming the reactants to promote the reaction CH4(g) + 6H2O(s→l) → CH4·6H2O (methane hydrate). Hydrate formation evidently occurs at the nascent ice/liquid water interface on ice grain surfaces, and complete reaction was achieved by warming the system above the ice melting point and up to 290 K, at 25−30 MPa, for approximately 8 h. The resulting material is pure, cohesive, polycrystalline methane hydrate with controlled grain size and random orientation. Synthesis conditions placed the H2O ice well above its melting temperature while reaction progressed, yet samples and run records showed no evidence for bulk melting of the unreacted portions of ice grains. Control experiments using Ne, a non-hydrate-forming gas, showed that under otherwise identical conditions, the pressure reduction and latent heat associated with ice melting are easily detectable in our fabrication apparatus. These results suggest that under hydrate-forming conditions, H2O ice can persist metastably to temperatures well above its ordinary melting point while reacting to form hydrate. Direct observations of the hydrate growth process in a small, high-pressure optical cell verified these conclusions and revealed additional details of the hydrate growth process. Methane hydrate samples were then tested in constant-strain-rate deformation experiments at T = 140−200 K, Pc = 50−100 MPa, and ε = 10-4−10-6 s-1. Measurements in both the brittle and ductile fields showed that methane hydrate has measurably different strength than H2O ice, and work hardens to an unusually high degree compared to other ices as well as to most metals and ceramics at high homologous temperatures. This work hardening may be related to a changing stoichiometry under pressure during plastic deformation; ... Article in Journal/Newspaper Methane hydrate OceanRep (GEOMAR Helmholtz Centre für Ocean Research Kiel) Energy & Fuels 12 2 201 211
institution Open Polar
collection OceanRep (GEOMAR Helmholtz Centre für Ocean Research Kiel)
op_collection_id ftoceanrep
language English
description We describe a new and efficient technique to grow aggregates of pure methane hydrate in quantities suitable for physical and material properties testing. Test specimens were grown under static conditions by combining cold, pressurized CH4 gas with granulated H2O ice, and then warming the reactants to promote the reaction CH4(g) + 6H2O(s→l) → CH4·6H2O (methane hydrate). Hydrate formation evidently occurs at the nascent ice/liquid water interface on ice grain surfaces, and complete reaction was achieved by warming the system above the ice melting point and up to 290 K, at 25−30 MPa, for approximately 8 h. The resulting material is pure, cohesive, polycrystalline methane hydrate with controlled grain size and random orientation. Synthesis conditions placed the H2O ice well above its melting temperature while reaction progressed, yet samples and run records showed no evidence for bulk melting of the unreacted portions of ice grains. Control experiments using Ne, a non-hydrate-forming gas, showed that under otherwise identical conditions, the pressure reduction and latent heat associated with ice melting are easily detectable in our fabrication apparatus. These results suggest that under hydrate-forming conditions, H2O ice can persist metastably to temperatures well above its ordinary melting point while reacting to form hydrate. Direct observations of the hydrate growth process in a small, high-pressure optical cell verified these conclusions and revealed additional details of the hydrate growth process. Methane hydrate samples were then tested in constant-strain-rate deformation experiments at T = 140−200 K, Pc = 50−100 MPa, and ε = 10-4−10-6 s-1. Measurements in both the brittle and ductile fields showed that methane hydrate has measurably different strength than H2O ice, and work hardens to an unusually high degree compared to other ices as well as to most metals and ceramics at high homologous temperatures. This work hardening may be related to a changing stoichiometry under pressure during plastic deformation; ...
format Article in Journal/Newspaper
author Stern, Laura A.
Kirby, Stephen H.
Durham, William B.
spellingShingle Stern, Laura A.
Kirby, Stephen H.
Durham, William B.
Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties
author_facet Stern, Laura A.
Kirby, Stephen H.
Durham, William B.
author_sort Stern, Laura A.
title Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties
title_short Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties
title_full Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties
title_fullStr Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties
title_full_unstemmed Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties
title_sort polycrystalline methane hydrate: synthesis from superheated ice, and low-temperature mechanical properties
publisher American Chemical Society
publishDate 1998
url https://oceanrep.geomar.de/id/eprint/42635/
https://oceanrep.geomar.de/id/eprint/42635/1/Stern,%20Kirby.pdf
https://doi.org/10.1021/ef970167m
genre Methane hydrate
genre_facet Methane hydrate
op_relation https://oceanrep.geomar.de/id/eprint/42635/1/Stern,%20Kirby.pdf
Stern, L. A., Kirby, S. H. and Durham, W. B. (1998) Polycrystalline Methane Hydrate: Synthesis from Superheated Ice, and Low-Temperature Mechanical Properties. Energy & Fuels, 12 (2). pp. 201-211. DOI 10.1021/ef970167m <https://doi.org/10.1021/ef970167m>.
doi:10.1021/ef970167m
op_rights info:eu-repo/semantics/restrictedAccess
op_doi https://doi.org/10.1021/ef970167m
container_title Energy & Fuels
container_volume 12
container_issue 2
container_start_page 201
op_container_end_page 211
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