Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis
The true contribution of gas desorption to shale gas production is often overshadowed by the use of adsorption isotherms for desorbed gas calculations on the assumption that both processes are identical under high pressure, high temperature conditions. In this study, three shale samples were used to...
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| Format: | Journal Article |
| Language: | English |
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MDPI
2019
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| Online Access: | http://hdl.handle.net/20.500.11937/89567 |
| _version_ | 1848765247465193472 |
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| author | Ekundayo, Jamiu Rezaee, Reza |
| author_facet | Ekundayo, Jamiu Rezaee, Reza |
| author_sort | Ekundayo, Jamiu |
| building | Curtin Institutional Repository |
| collection | Online Access |
| description | The true contribution of gas desorption to shale gas production is often overshadowed by the use of adsorption isotherms for desorbed gas calculations on the assumption that both processes are identical under high pressure, high temperature conditions. In this study, three shale samples were used to study the adsorption and desorption isotherms of methane at a temperature of 80 ◦C, using volumetric method. The resulting isotherms were modeled using the Langmuir model, following the conversion of measured excess amounts to absolute values. All three samples exhibited significant hysteresis between the sorption processes and the desorption isotherms gave lower Langmuir parameters than the corresponding adsorption isotherms. Langmuir volume showed positive correlation with total organic carbon (TOC) content for both sorption processes. A compositional three-dimensional (3D), dual-porosity model was then developed in GEM® (a product of the Computer Modelling Group (CMG) Ltd., Calgary, AB, Canada) to test the effect of the observed hysteresis on shale gas production. For each sample, a base scenario, corresponding to a “no-sorption” case was compared against two other cases; one with adsorption Langmuir parameters (adsorption case) and the other with desorption Langmuir parameters (desorption case). The simulation results showed that while gas production can be significantly under-predicted if gas sorption is not considered, the use of adsorption isotherms in lieu of desorption can lead to over-prediction of gas production performances. |
| first_indexed | 2025-11-14T11:32:13Z |
| format | Journal Article |
| id | curtin-20.500.11937-89567 |
| institution | Curtin University Malaysia |
| institution_category | Local University |
| language | English |
| last_indexed | 2025-11-14T11:32:13Z |
| publishDate | 2019 |
| publisher | MDPI |
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| spelling | curtin-20.500.11937-895672022-11-18T05:51:44Z Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis Ekundayo, Jamiu Rezaee, Reza Science & Technology Technology Energy & Fuels organic-rich shale gas adsorption and desorption sorption hysteresis Langmuir model compositional 3D dual-porosity system total organic carbon (TOC) Computer Modelling Group (CMG) GEM((R)) CARBON-DIOXIDE HIGH-PRESSURE METHANE ADSORPTION DESORPTION DENSITY MODEL TEMPERATURE TRANSPORT NITROGEN EQUATION The true contribution of gas desorption to shale gas production is often overshadowed by the use of adsorption isotherms for desorbed gas calculations on the assumption that both processes are identical under high pressure, high temperature conditions. In this study, three shale samples were used to study the adsorption and desorption isotherms of methane at a temperature of 80 ◦C, using volumetric method. The resulting isotherms were modeled using the Langmuir model, following the conversion of measured excess amounts to absolute values. All three samples exhibited significant hysteresis between the sorption processes and the desorption isotherms gave lower Langmuir parameters than the corresponding adsorption isotherms. Langmuir volume showed positive correlation with total organic carbon (TOC) content for both sorption processes. A compositional three-dimensional (3D), dual-porosity model was then developed in GEM® (a product of the Computer Modelling Group (CMG) Ltd., Calgary, AB, Canada) to test the effect of the observed hysteresis on shale gas production. For each sample, a base scenario, corresponding to a “no-sorption” case was compared against two other cases; one with adsorption Langmuir parameters (adsorption case) and the other with desorption Langmuir parameters (desorption case). The simulation results showed that while gas production can be significantly under-predicted if gas sorption is not considered, the use of adsorption isotherms in lieu of desorption can lead to over-prediction of gas production performances. 2019 Journal Article http://hdl.handle.net/20.500.11937/89567 10.3390/en12183405 English http://creativecommons.org/licenses/by/4.0/ MDPI fulltext |
| spellingShingle | Science & Technology Technology Energy & Fuels organic-rich shale gas adsorption and desorption sorption hysteresis Langmuir model compositional 3D dual-porosity system total organic carbon (TOC) Computer Modelling Group (CMG) GEM((R)) CARBON-DIOXIDE HIGH-PRESSURE METHANE ADSORPTION DESORPTION DENSITY MODEL TEMPERATURE TRANSPORT NITROGEN EQUATION Ekundayo, Jamiu Rezaee, Reza Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| title | Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| title_full | Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| title_fullStr | Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| title_full_unstemmed | Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| title_short | Numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| title_sort | numerical simulation of gas production from gas shale reservoirs—influence of gas sorption hysteresis |
| topic | Science & Technology Technology Energy & Fuels organic-rich shale gas adsorption and desorption sorption hysteresis Langmuir model compositional 3D dual-porosity system total organic carbon (TOC) Computer Modelling Group (CMG) GEM((R)) CARBON-DIOXIDE HIGH-PRESSURE METHANE ADSORPTION DESORPTION DENSITY MODEL TEMPERATURE TRANSPORT NITROGEN EQUATION |
| url | http://hdl.handle.net/20.500.11937/89567 |