Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir
The ongoing search for new sources of energy has brought natural gas hydrate (NGH) reservoirs to the forefront of attention in both academia and the industry. The amount of gas reserves trapped within these reservoirs surpasses all of the conventional fossil fuel sources explored so far, which makes...
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ftrepec:oai:RePEc:gam:jeners:v:10:y:2017:i:7:p:1064-:d:105578 |
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ftrepec:oai:RePEc:gam:jeners:v:10:y:2017:i:7:p:1064-:d:105578 2024-04-14T08:14:52+00:00 Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir Khadijeh Qorbani Bjørn Kvamme Tatiana Kuznetsova https://www.mdpi.com/1996-1073/10/7/1064/pdf https://www.mdpi.com/1996-1073/10/7/1064/ unknown https://www.mdpi.com/1996-1073/10/7/1064/pdf https://www.mdpi.com/1996-1073/10/7/1064/ article ftrepec 2024-03-19T10:31:35Z The ongoing search for new sources of energy has brought natural gas hydrate (NGH) reservoirs to the forefront of attention in both academia and the industry. The amount of gas reserves trapped within these reservoirs surpasses all of the conventional fossil fuel sources explored so far, which makes it of utmost importance to predict their production potential and safety. One of the challenges facing those attempting to analyse their behaviour is that the large number of involved phases make NGHs unable to ever reach equilibrium in nature. Field-scale experiments are expensive and time consuming. However, computer simulations have now become capable of modelling different gas production scenarios, as well as production optimization analyses. In addition to temperature and pressure, independent thermodynamic parameters for hydrate stabilization include the hydrate composition and concentrations for all co-existing phases. It is therefore necessary to develop and implement realistic kinetic models accounting for all significant routes for dissociation and reformation. The reactive transport simulator makes it easy to deploy nonequilibrium thermodynamics for the study of CH 4 production from hydrate-bearing sediments by considering each hydrate-related transition as a separate pseudo reaction. In this work, we have used the expanded version of the RetrasoCodeBright (RCB) reactive transport simulator to model exploitation of the methane hydrate (MH) reservoir located in the Nankai Trough, Japan. Our results showed that higher permeabilities in the horizontal direction dominated the pressure drop propagation throughout the hydrate layers and affected their hydrate dissociation rates. Additionally, the comparison of the vertical well versus the horizontal well pattern indicated that hydrate dissociation was slightly higher in the vertical well scenario compared to the horizontal. methane hydrate; gas hydrate production; Nankai Trough; reservoir simulation; reactive transport; non-equilibrium thermodynamic Article in Journal/Newspaper Methane hydrate RePEc (Research Papers in Economics) |
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Open Polar |
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RePEc (Research Papers in Economics) |
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ftrepec |
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unknown |
| description |
The ongoing search for new sources of energy has brought natural gas hydrate (NGH) reservoirs to the forefront of attention in both academia and the industry. The amount of gas reserves trapped within these reservoirs surpasses all of the conventional fossil fuel sources explored so far, which makes it of utmost importance to predict their production potential and safety. One of the challenges facing those attempting to analyse their behaviour is that the large number of involved phases make NGHs unable to ever reach equilibrium in nature. Field-scale experiments are expensive and time consuming. However, computer simulations have now become capable of modelling different gas production scenarios, as well as production optimization analyses. In addition to temperature and pressure, independent thermodynamic parameters for hydrate stabilization include the hydrate composition and concentrations for all co-existing phases. It is therefore necessary to develop and implement realistic kinetic models accounting for all significant routes for dissociation and reformation. The reactive transport simulator makes it easy to deploy nonequilibrium thermodynamics for the study of CH 4 production from hydrate-bearing sediments by considering each hydrate-related transition as a separate pseudo reaction. In this work, we have used the expanded version of the RetrasoCodeBright (RCB) reactive transport simulator to model exploitation of the methane hydrate (MH) reservoir located in the Nankai Trough, Japan. Our results showed that higher permeabilities in the horizontal direction dominated the pressure drop propagation throughout the hydrate layers and affected their hydrate dissociation rates. Additionally, the comparison of the vertical well versus the horizontal well pattern indicated that hydrate dissociation was slightly higher in the vertical well scenario compared to the horizontal. methane hydrate; gas hydrate production; Nankai Trough; reservoir simulation; reactive transport; non-equilibrium thermodynamic |
| format |
Article in Journal/Newspaper |
| author |
Khadijeh Qorbani Bjørn Kvamme Tatiana Kuznetsova |
| spellingShingle |
Khadijeh Qorbani Bjørn Kvamme Tatiana Kuznetsova Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir |
| author_facet |
Khadijeh Qorbani Bjørn Kvamme Tatiana Kuznetsova |
| author_sort |
Khadijeh Qorbani |
| title |
Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir |
| title_short |
Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir |
| title_full |
Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir |
| title_fullStr |
Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir |
| title_full_unstemmed |
Utilizing Non-Equilibrium Thermodynamics and Reactive Transport to Model CH 4 Production from the Nankai Trough Gas Hydrate Reservoir |
| title_sort |
utilizing non-equilibrium thermodynamics and reactive transport to model ch 4 production from the nankai trough gas hydrate reservoir |
| url |
https://www.mdpi.com/1996-1073/10/7/1064/pdf https://www.mdpi.com/1996-1073/10/7/1064/ |
| genre |
Methane hydrate |
| genre_facet |
Methane hydrate |
| op_relation |
https://www.mdpi.com/1996-1073/10/7/1064/pdf https://www.mdpi.com/1996-1073/10/7/1064/ |
| _version_ |
1796313103624830976 |