Gas production from hydrate-bearing sediments:geo-mechanical implications
Gas hydrate consists of guest gas molecules encaged in water molecules. Methane is the most common guest molecule in natural hydrates. Methane hydrate forms under high fluid pressure and low temperature and is found in marine sediments or in permafrost region. Methane hydrate can be an energy resour...
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Georgia Institute of Technology
2010
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| Online Access: | http://hdl.handle.net/1853/42841 |
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ftgeorgiatech:oai:repository.gatech.edu:1853/42841 2024-06-02T08:10:24+00:00 Gas production from hydrate-bearing sediments:geo-mechanical implications Jung, Jongwon Santamarina, J. Carlos Burns, Susan Elizabeth Goldsztein, Guillermo Huang, Haiying Ruppel, Carolyn. D. Tsouris, Costas Civil and Environmental Engineering 2010-11-10 application/pdf http://hdl.handle.net/1853/42841 unknown Georgia Institute of Technology http://hdl.handle.net/1853/42841 Discrete element method Gas production Replacement Hydrate Sediments (Geology) Marine sediments Marine sediments Gas content Methane Natural gas Hydrates Hydrates Text Dissertation 2010 ftgeorgiatech 2024-05-06T11:21:29Z Gas hydrate consists of guest gas molecules encaged in water molecules. Methane is the most common guest molecule in natural hydrates. Methane hydrate forms under high fluid pressure and low temperature and is found in marine sediments or in permafrost region. Methane hydrate can be an energy resource (world reserves are estimated in 20,000 trillion m3 of CH4), contribute to global warming, or cause seafloor instability. Research documented in this thesis starts with an investigation of hydrate formation and growth in the pores, and the assessment of formation rate, tensile/adhesive strength and their impact on sediment-scale properties, including volume change during hydrate formation and dissociation. Then, emphasis is placed on identifying the advantages and limitations of different gas production strategies with emphasis on a detailed study of CH4-CO2 exchange as a unique alternative to recover CH4 gas while sequestering CO2. The research methodology combines experimental studies, particle-scale numerical simulations, and macro-scale analyses of coupled processes. PhD Doctoral or Postdoctoral Thesis Methane hydrate permafrost Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech |
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Open Polar |
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Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech |
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ftgeorgiatech |
| language |
unknown |
| topic |
Discrete element method Gas production Replacement Hydrate Sediments (Geology) Marine sediments Marine sediments Gas content Methane Natural gas Hydrates Hydrates |
| spellingShingle |
Discrete element method Gas production Replacement Hydrate Sediments (Geology) Marine sediments Marine sediments Gas content Methane Natural gas Hydrates Hydrates Jung, Jongwon Gas production from hydrate-bearing sediments:geo-mechanical implications |
| topic_facet |
Discrete element method Gas production Replacement Hydrate Sediments (Geology) Marine sediments Marine sediments Gas content Methane Natural gas Hydrates Hydrates |
| description |
Gas hydrate consists of guest gas molecules encaged in water molecules. Methane is the most common guest molecule in natural hydrates. Methane hydrate forms under high fluid pressure and low temperature and is found in marine sediments or in permafrost region. Methane hydrate can be an energy resource (world reserves are estimated in 20,000 trillion m3 of CH4), contribute to global warming, or cause seafloor instability. Research documented in this thesis starts with an investigation of hydrate formation and growth in the pores, and the assessment of formation rate, tensile/adhesive strength and their impact on sediment-scale properties, including volume change during hydrate formation and dissociation. Then, emphasis is placed on identifying the advantages and limitations of different gas production strategies with emphasis on a detailed study of CH4-CO2 exchange as a unique alternative to recover CH4 gas while sequestering CO2. The research methodology combines experimental studies, particle-scale numerical simulations, and macro-scale analyses of coupled processes. PhD |
| author2 |
Santamarina, J. Carlos Burns, Susan Elizabeth Goldsztein, Guillermo Huang, Haiying Ruppel, Carolyn. D. Tsouris, Costas Civil and Environmental Engineering |
| format |
Doctoral or Postdoctoral Thesis |
| author |
Jung, Jongwon |
| author_facet |
Jung, Jongwon |
| author_sort |
Jung, Jongwon |
| title |
Gas production from hydrate-bearing sediments:geo-mechanical implications |
| title_short |
Gas production from hydrate-bearing sediments:geo-mechanical implications |
| title_full |
Gas production from hydrate-bearing sediments:geo-mechanical implications |
| title_fullStr |
Gas production from hydrate-bearing sediments:geo-mechanical implications |
| title_full_unstemmed |
Gas production from hydrate-bearing sediments:geo-mechanical implications |
| title_sort |
gas production from hydrate-bearing sediments:geo-mechanical implications |
| publisher |
Georgia Institute of Technology |
| publishDate |
2010 |
| url |
http://hdl.handle.net/1853/42841 |
| genre |
Methane hydrate permafrost |
| genre_facet |
Methane hydrate permafrost |
| op_relation |
http://hdl.handle.net/1853/42841 |
| _version_ |
1800756259442393088 |