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Main Authors: Ramadhan, Romal, Promneewat, Khomchan, Thanasaksukthawee, Vorasate, Tosuai, Teerapat, Babaei, Masoud, Hosseini, Seyyed A., Puttiwongrak, Avirut, Leelasukseree, Cheowchan, Tangparitkul, Suparit
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.14422
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author Ramadhan, Romal
Promneewat, Khomchan
Thanasaksukthawee, Vorasate
Tosuai, Teerapat
Babaei, Masoud
Hosseini, Seyyed A.
Puttiwongrak, Avirut
Leelasukseree, Cheowchan
Tangparitkul, Suparit
author_facet Ramadhan, Romal
Promneewat, Khomchan
Thanasaksukthawee, Vorasate
Tosuai, Teerapat
Babaei, Masoud
Hosseini, Seyyed A.
Puttiwongrak, Avirut
Leelasukseree, Cheowchan
Tangparitkul, Suparit
contents Recognized as a not-an-option approach to mitigate the climate crisis, carbon dioxide capture and storage (CCS) has a potential as much as gigaton of CO2 to sequestrate permanently and securely. Recent attention has been paid to store highly concentrated point-source CO2 into saline formation, of which Thailand considers one onshore case in the north located in Lampang, the Mae Moh coal-fired power plant matched with its own coal mine of Mae Moh Basin. The current study is thus aimed to examine the influence of reservoir geomechanics on CO2 storage containment and trapping mechanisms, with co-contributions from geochemistry and reservoir heterogeneity, using reservoir simulator, CMG-GEM. With the injection rate designed for 30-year injection, reservoir pressure build-ups were 77% of fracture pressure but increased to 80% when geomechanics excluded. Such pressure responses imply that storage security is associated with the geomechanics. Dominated by viscous force, CO2 plume migrated more laterally while geomechanics clearly contributed to lesser migration due to reservoir rock strength constraint. Reservoir geomechanics contributed to less plume traveling into more constrained spaces while leakage was secured, highlighting a significant and neglected influence of geomechanical factor. Spatiotemporal development of CO2 plume also confirms the geomechanics-dominant storage containment. Reservoir geomechanics as attributed to its respective reservoir fluid pressure controls development of trapping mechanisms, especially into residual and solubility traps. More secured storage containment after the injection was found with higher pressure, while less development into solubility trap was observed with lower pressure.
format Preprint
id arxiv_https___arxiv_org_abs_2404_14422
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Geomechanics Contribution to CO2 Storage Containment and Trapping Mechanisms in Tight Sandstone Complexes: A Case Study on Mae Moh Basin
Ramadhan, Romal
Promneewat, Khomchan
Thanasaksukthawee, Vorasate
Tosuai, Teerapat
Babaei, Masoud
Hosseini, Seyyed A.
Puttiwongrak, Avirut
Leelasukseree, Cheowchan
Tangparitkul, Suparit
Geophysics
Recognized as a not-an-option approach to mitigate the climate crisis, carbon dioxide capture and storage (CCS) has a potential as much as gigaton of CO2 to sequestrate permanently and securely. Recent attention has been paid to store highly concentrated point-source CO2 into saline formation, of which Thailand considers one onshore case in the north located in Lampang, the Mae Moh coal-fired power plant matched with its own coal mine of Mae Moh Basin. The current study is thus aimed to examine the influence of reservoir geomechanics on CO2 storage containment and trapping mechanisms, with co-contributions from geochemistry and reservoir heterogeneity, using reservoir simulator, CMG-GEM. With the injection rate designed for 30-year injection, reservoir pressure build-ups were 77% of fracture pressure but increased to 80% when geomechanics excluded. Such pressure responses imply that storage security is associated with the geomechanics. Dominated by viscous force, CO2 plume migrated more laterally while geomechanics clearly contributed to lesser migration due to reservoir rock strength constraint. Reservoir geomechanics contributed to less plume traveling into more constrained spaces while leakage was secured, highlighting a significant and neglected influence of geomechanical factor. Spatiotemporal development of CO2 plume also confirms the geomechanics-dominant storage containment. Reservoir geomechanics as attributed to its respective reservoir fluid pressure controls development of trapping mechanisms, especially into residual and solubility traps. More secured storage containment after the injection was found with higher pressure, while less development into solubility trap was observed with lower pressure.
title Geomechanics Contribution to CO2 Storage Containment and Trapping Mechanisms in Tight Sandstone Complexes: A Case Study on Mae Moh Basin
topic Geophysics
url https://arxiv.org/abs/2404.14422