The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?

The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?

Monitoring, verification, and accounting (MVA) of CO2 fate which are the three fundamental needs in geological sequestration are discussed. The primary objective of MVA protocols is to identify and quantify the injected CO2 stream within the injection/storage horizon and any leakage of sequestered g...

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Main Authors: Vanorio, T., Mavko, G., Vialle, Stephanie, Spratt, K.
Format: Journal Article
Published: Society of Exploration Geophysicists 2010
Online Access:http://hdl.handle.net/20.500.11937/25958
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author Vanorio, T.
Mavko, G.
Vialle, Stephanie
Spratt, K.
author_facet Vanorio, T.
Mavko, G.
Vialle, Stephanie
Spratt, K.
author_sort Vanorio, T.
building Curtin Institutional Repository
collection Online Access
description Monitoring, verification, and accounting (MVA) of CO2 fate which are the three fundamental needs in geological sequestration are discussed. The primary objective of MVA protocols is to identify and quantify the injected CO2 stream within the injection/storage horizon and any leakage of sequestered gas from the injection horizon, providing public assurance. Changes in the elastic properties of the reservoir induced by the injection of CO2 can be various, affecting the properties of the fluid, those of the rock frame, or both. Seismic reservoir monitoring has traditionally treated the changes in the reservoir rock as a physical-mechanical problem, that is changes in seismic signatures are mostly modeled as functions of saturation and stress variations and/or intrinsic rock properties. To enhance the effectiveness of time-lapse seismic studies, CO2-optimized physical-chemical models involving frame substitution schemes must be developed to account for the type and magnitude of reductions caused by rock-fluid interactions at the grain/pore scale.
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institution Curtin University Malaysia
institution_category Local University
last_indexed 2025-11-14T07:59:17Z
publishDate 2010
publisher Society of Exploration Geophysicists
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spelling curtin-20.500.11937-259582017-09-13T15:24:46Z The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet? Vanorio, T. Mavko, G. Vialle, Stephanie Spratt, K. Monitoring, verification, and accounting (MVA) of CO2 fate which are the three fundamental needs in geological sequestration are discussed. The primary objective of MVA protocols is to identify and quantify the injected CO2 stream within the injection/storage horizon and any leakage of sequestered gas from the injection horizon, providing public assurance. Changes in the elastic properties of the reservoir induced by the injection of CO2 can be various, affecting the properties of the fluid, those of the rock frame, or both. Seismic reservoir monitoring has traditionally treated the changes in the reservoir rock as a physical-mechanical problem, that is changes in seismic signatures are mostly modeled as functions of saturation and stress variations and/or intrinsic rock properties. To enhance the effectiveness of time-lapse seismic studies, CO2-optimized physical-chemical models involving frame substitution schemes must be developed to account for the type and magnitude of reductions caused by rock-fluid interactions at the grain/pore scale. 2010 Journal Article http://hdl.handle.net/20.500.11937/25958 10.1190/1.3304818 Society of Exploration Geophysicists restricted
spellingShingle Vanorio, T.
Mavko, G.
Vialle, Stephanie
Spratt, K.
The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?
title The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?
title_full The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?
title_fullStr The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?
title_full_unstemmed The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?
title_short The rock physics basis for 4D seismic monitoring of CO2 fate: Are we there yet?
title_sort rock physics basis for 4d seismic monitoring of co2 fate: are we there yet?
url http://hdl.handle.net/20.500.11937/25958

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