Integrated geophysical and hydromechanical assessment for CO2 storage: shallow low permeable reservoir sandstones
Integrated geophysical and hydromechanical assessment for CO2 storage: shallow low permeable reservoir sandstones
Geological reservoirs can be structurally complex and can respond to CO2 injection both geochemically and geomechanically. Hence, predicting reservoir formation behaviour in response to CO2 injection and assessing the resulting hazards are important prerequisites for safe geological CO2 storage. This requires a detailed study of thermal-hydro-mechanical-chemical coupled phenomena that can be triggered in the reservoir formation, most readily achieved through laboratory simulations of CO2 injection into typical reservoir formations. Here, we present the first results from a new experimental apparatus of a steady-state drainage flooding test conducted through a synthetic sandstone sample, simulating real CO2 storage reservoir conditions in a shallow (?1 km), low permeability ?1mD, 26% porosity sandstone formation. The injected pore fluid comprised brine with CO2 saturation increasing in steps of 20% brine/CO2 partial flow rates up to 100% CO2 flow. At each pore fluid stage, an unload/loading cycle of effective pressure was imposed to study the response of the rock under different geomechanical scenarios. The monitoring included axial strains and relative permeability in a continuous mode (hydromechanical assessment), and related geophysical signatures (ultrasonic P-wave and S-wave velocities Vp and Vs, and attenuations Qp?1 and Qs?1, respectively, and electrical resistivity). On average, the results showed Vp and Vs dropped ?7% and ?4% respectively during the test, whereas Qp?1 increased ?55% and Qs?1 decreased by ?25%. From the electrical resistivity data, we estimated a maximum CO2 saturation of ?0.5, whereas relative permeability curves were adjusted for both fluids. Comparing the experimental results to theoretical predictions, we found that Gassmann's equations explain Vp at high and very low CO2 saturations, whereas bulk modulus yields results consistent with White and Dutta–Odé model predictions. This is interpreted as a heterogeneous distribution of the two pore fluid phases, corroborated by electrical resistivity tomography images. The integration of laboratory geophysical and hydromechanical observations on representative shallow low-permeable sandstone reservoir allowed us to distinguish between pure geomechanical responses and those associated with the pore fluid distribution. This is a key aspect in understanding CO2 injection effects in deep geological reservoirs associated with carbon capture and storage practices.
Seismic velocity, Attenuation, Electrical resistivity, Permeability, CO2 injection, Reservoir geophysics
828-847
Falcon-Suarez, Ismael
9e8022b5-8799-4326-8d5b-0ed46de3b25a
North, Laurence
52411b5f-b0b4-4e67-adc3-f5f5b63f3d69
Amalokwu, Kelvin
a88bc1e5-5577-49a6-a503-fcd9ea12d8fe
Best, Angus
cad03726-10f8-4f90-a3ba-5031665234c9
28 June 2016
Falcon-Suarez, Ismael
9e8022b5-8799-4326-8d5b-0ed46de3b25a
North, Laurence
52411b5f-b0b4-4e67-adc3-f5f5b63f3d69
Amalokwu, Kelvin
a88bc1e5-5577-49a6-a503-fcd9ea12d8fe
Best, Angus
cad03726-10f8-4f90-a3ba-5031665234c9
Falcon-Suarez, Ismael, North, Laurence, Amalokwu, Kelvin and Best, Angus
(2016)
Integrated geophysical and hydromechanical assessment for CO2 storage: shallow low permeable reservoir sandstones.
Geophysical Prospecting, 64 (4), .
(doi:10.1111/1365-2478.12396).
Abstract
Geological reservoirs can be structurally complex and can respond to CO2 injection both geochemically and geomechanically. Hence, predicting reservoir formation behaviour in response to CO2 injection and assessing the resulting hazards are important prerequisites for safe geological CO2 storage. This requires a detailed study of thermal-hydro-mechanical-chemical coupled phenomena that can be triggered in the reservoir formation, most readily achieved through laboratory simulations of CO2 injection into typical reservoir formations. Here, we present the first results from a new experimental apparatus of a steady-state drainage flooding test conducted through a synthetic sandstone sample, simulating real CO2 storage reservoir conditions in a shallow (?1 km), low permeability ?1mD, 26% porosity sandstone formation. The injected pore fluid comprised brine with CO2 saturation increasing in steps of 20% brine/CO2 partial flow rates up to 100% CO2 flow. At each pore fluid stage, an unload/loading cycle of effective pressure was imposed to study the response of the rock under different geomechanical scenarios. The monitoring included axial strains and relative permeability in a continuous mode (hydromechanical assessment), and related geophysical signatures (ultrasonic P-wave and S-wave velocities Vp and Vs, and attenuations Qp?1 and Qs?1, respectively, and electrical resistivity). On average, the results showed Vp and Vs dropped ?7% and ?4% respectively during the test, whereas Qp?1 increased ?55% and Qs?1 decreased by ?25%. From the electrical resistivity data, we estimated a maximum CO2 saturation of ?0.5, whereas relative permeability curves were adjusted for both fluids. Comparing the experimental results to theoretical predictions, we found that Gassmann's equations explain Vp at high and very low CO2 saturations, whereas bulk modulus yields results consistent with White and Dutta–Odé model predictions. This is interpreted as a heterogeneous distribution of the two pore fluid phases, corroborated by electrical resistivity tomography images. The integration of laboratory geophysical and hydromechanical observations on representative shallow low-permeable sandstone reservoir allowed us to distinguish between pure geomechanical responses and those associated with the pore fluid distribution. This is a key aspect in understanding CO2 injection effects in deep geological reservoirs associated with carbon capture and storage practices.
Text
GP_2015_0062_R2.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 1 January 2016
e-pub ahead of print date: 28 June 2016
Published date: 28 June 2016
Keywords:
Seismic velocity, Attenuation, Electrical resistivity, Permeability, CO2 injection, Reservoir geophysics
Organisations:
Geology & Geophysics, Marine Geoscience
Identifiers
Local EPrints ID: 397503
URI: http://eprints.soton.ac.uk/id/eprint/397503
ISSN: 0016-8025
PURE UUID: 0773bc45-1359-47ca-bd80-acfa6b3bdb8b
Catalogue record
Date deposited: 29 Jun 2016 08:37
Last modified: 15 Mar 2024 05:42
Export record
Altmetrics
Contributors
Author:
Ismael Falcon-Suarez
Author:
Laurence North
Author:
Kelvin Amalokwu
Author:
Angus Best
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics