Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot

This study is a small part of ongoing research for CO2 sequestration at Longyearbyen CO2 Storage Lab, Svalbard, Norway. The primary aim of this study is to determine geomechanical properties of two important caprock units to assess the integrity of sealing for safe and successful CO2 storage in the...

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Bibliographic Details
Main Author: Abbas, Mohsin
Format: Master Thesis
Language:English
Published: 2015
Subjects:
Geomechanical
properties
caprock
Tensile
strength
Uniaxial
compressive
Agardhfjellet
Longyearbyen
Norway
Rurikfjellet
Svalbard
UNIS
Online Access:http://hdl.handle.net/10852/45438
http://urn.nb.no/URN:NBN:no-49847
id ftoslouniv:oai:www.duo.uio.no:10852/45438
record_format openpolar
institution Open Polar
collection Universitet i Oslo: Digitale utgivelser ved UiO (DUO)
op_collection_id ftoslouniv
language English
topic Geomechanical
properties
caprock
Tensile
strength
Uniaxial
compressive
spellingShingle Geomechanical
properties
caprock
Tensile
strength
Uniaxial
compressive
Abbas, Mohsin
Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot
topic_facet Geomechanical
properties
caprock
Tensile
strength
Uniaxial
compressive
description This study is a small part of ongoing research for CO2 sequestration at Longyearbyen CO2 Storage Lab, Svalbard, Norway. The primary aim of this study is to determine geomechanical properties of two important caprock units to assess the integrity of sealing for safe and successful CO2 storage in the future. Core materials for this study are provided by UNIS CO2 Lab that previously collected and stored by the Norwegian Geotechnical Institute (NGI). Results from this study are compared with previous work performed by NGI in 2010, 2012 and 2014. Six core samples were selected from well Dh-6 targeting cap rock unit of Longyearbyen CO2 storage lab, consists mainly of two geological formations; Rurikfjellet and Agardhfjellet in depth range 308.00-428.28 m. All the samples were well preserved in paraffin sealing and kept in the controlled temperature room at NGI. Samples were unsealed and inspected for any pre-existing defects e.g. fractures or any damage. These cores were cut to make plugs according to the ASTM standard for Brazilian and UCS tests. The diameter and thickness of disc shaped plugs for Brazilian test are 40-40.5mm and 19-21mm respectively. The diameters and heights of cylindrical plugs for UCS tests are 40.4 and 28 mm and 82 and 60 mm respectively. Two geomechanical laboratory tests; Brazilian and Uniaxial compressive strength tests were performed on the prepared plugs to determine tensile and uniaxial compressive strength respectively. A detailed study of tensile strength was executed on a set of ten disc shaped plugs from two different geological units; Rurikfjellet and Agardhfjellet formations at certain depth ranges 308.00 to 386.89 m and 425.28 to 428.28 m respectively. Before performing laboratory tests on these plugs, density was measured and also a detailed analysis of bulk mineralogy and mineral identification plus micro-structure (only three thin section were made) study was carried out using X-ray diffraction (XRD) and scanning electron microscopy (SEM) respectively. All these plugs were loaded perpendicular to the bedding planes and that is why the calculated strength was called vertical tensile strength. Almost all the plugs were failed in expected time according to ISRM standard and the pattern of produced fractures after the test is also as expected. Variations based on tensile strength are higher in Agardhfjellet formation (2.29-10.35 MPa) as compared to Rurikfjellet formation (3.96-5.53 MPa). Estimation of tensile strength for a cap rock can be very important aspect, especially when it is subjected to a fluid injection into a subsurface reservoir. The information of tensile strength can be used to avoid hydraulic fracturing caused by fluid injection, also fracture propagation and its nature can be determined. Uniaxial compressive strength test is also performed on a set of six plugs. Four of the plugs were tested from Rurikfjellet Formation (depth range 308.00 to 369.53 m) and two plugs were tested from Agardhfjellet Formation (depth range 425.28 to 428.28 m). Most of the tested plugs were failed within the time frame mentioned in ASTM standards for UCS test and few of the plugs show very clear shear failure. Mainly geomechanical parameters [uniaxial compressive strength (σ), Young s modulus (E) for axial deformation] and P- and S-wave velocities are measured from this test. Variations of these all three measurements are analyzed within each formation and also compared with each other. Agardhfjellet Formation has highest values in these measurements as compared to Rurikfjellet Formation. Index test from UCS can be utilized to estimate overburden pressure of rocks and behavior of material when it is subjected to compression in uniaxial directions. Furthermore this data can be used for various modelling of the caprock/seal evaluation. Finally results from Brazilian and uniaxial compressive strength test are compared with previous work performed at NGI. The previous work of NGI was done on core samples from wells Dh-2, Dh-4 and Dh-6 from different formations, also including Rurikfjellet and Agardhfjellet formations at different depths. Results from this study from similar depth are matching with previous results. The overall rock strengths (UCS and tensile strength) are higher at deeper intervals. Reasons can be the compaction, cementation, etc. For more accurate and better understandings of caprock integrity to ensure safe CO2 storage, further research is required than this study. For instance, more core samples should be tested from Agardhfjellet formation because in this study only two were tested and both are very different in all reported parameters. Therefore, evaluation of an entire formation would not be appropriate on the basis of few tested samples. Fracture analysis could be done for both macro and micro levels but it was not considered here due to limited data sources, laboratory facilities and time constraint, though it is highly recommended and can be very useful for the leakage risk assessment in the caprock.
format Master Thesis
author Abbas, Mohsin
author_facet Abbas, Mohsin
author_sort Abbas, Mohsin
title Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot
title_short Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot
title_full Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot
title_fullStr Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot
title_full_unstemmed Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot
title_sort geomechanical characterization of shale caprock of the longyearbyen co2 storage pilot
publishDate 2015
url http://hdl.handle.net/10852/45438
http://urn.nb.no/URN:NBN:no-49847
long_lat ENVELOPE(18.833,18.833,78.083,78.083)
ENVELOPE(18.217,18.217,77.983,77.983)
geographic Agardhfjellet
Longyearbyen
Norway
Rurikfjellet
Svalbard
geographic_facet Agardhfjellet
Longyearbyen
Norway
Rurikfjellet
Svalbard
genre Longyearbyen
Svalbard
UNIS
genre_facet Longyearbyen
Svalbard
UNIS
op_relation http://urn.nb.no/URN:NBN:no-49847
Abbas, Mohsin. Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot. Master thesis, University of Oslo, 2015
http://hdl.handle.net/10852/45438
URN:NBN:no-49847
Fulltext https://www.duo.uio.no/bitstream/handle/10852/45438/14/MSc-Thesis_Mohsin_Abbas_30-05-2015modified.pdf
_version_ 1766064278549299200
spelling ftoslouniv:oai:www.duo.uio.no:10852/45438 2023-05-15T17:08:30+02:00 Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot Abbas, Mohsin 2015 http://hdl.handle.net/10852/45438 http://urn.nb.no/URN:NBN:no-49847 eng eng http://urn.nb.no/URN:NBN:no-49847 Abbas, Mohsin. Geomechanical characterization of shale caprock of the Longyearbyen CO2 storage pilot. Master thesis, University of Oslo, 2015 http://hdl.handle.net/10852/45438 URN:NBN:no-49847 Fulltext https://www.duo.uio.no/bitstream/handle/10852/45438/14/MSc-Thesis_Mohsin_Abbas_30-05-2015modified.pdf Geomechanical properties caprock Tensile strength Uniaxial compressive Master thesis Masteroppgave 2015 ftoslouniv 2020-06-21T08:48:36Z This study is a small part of ongoing research for CO2 sequestration at Longyearbyen CO2 Storage Lab, Svalbard, Norway. The primary aim of this study is to determine geomechanical properties of two important caprock units to assess the integrity of sealing for safe and successful CO2 storage in the future. Core materials for this study are provided by UNIS CO2 Lab that previously collected and stored by the Norwegian Geotechnical Institute (NGI). Results from this study are compared with previous work performed by NGI in 2010, 2012 and 2014. Six core samples were selected from well Dh-6 targeting cap rock unit of Longyearbyen CO2 storage lab, consists mainly of two geological formations; Rurikfjellet and Agardhfjellet in depth range 308.00-428.28 m. All the samples were well preserved in paraffin sealing and kept in the controlled temperature room at NGI. Samples were unsealed and inspected for any pre-existing defects e.g. fractures or any damage. These cores were cut to make plugs according to the ASTM standard for Brazilian and UCS tests. The diameter and thickness of disc shaped plugs for Brazilian test are 40-40.5mm and 19-21mm respectively. The diameters and heights of cylindrical plugs for UCS tests are 40.4 and 28 mm and 82 and 60 mm respectively. Two geomechanical laboratory tests; Brazilian and Uniaxial compressive strength tests were performed on the prepared plugs to determine tensile and uniaxial compressive strength respectively. A detailed study of tensile strength was executed on a set of ten disc shaped plugs from two different geological units; Rurikfjellet and Agardhfjellet formations at certain depth ranges 308.00 to 386.89 m and 425.28 to 428.28 m respectively. Before performing laboratory tests on these plugs, density was measured and also a detailed analysis of bulk mineralogy and mineral identification plus micro-structure (only three thin section were made) study was carried out using X-ray diffraction (XRD) and scanning electron microscopy (SEM) respectively. All these plugs were loaded perpendicular to the bedding planes and that is why the calculated strength was called vertical tensile strength. Almost all the plugs were failed in expected time according to ISRM standard and the pattern of produced fractures after the test is also as expected. Variations based on tensile strength are higher in Agardhfjellet formation (2.29-10.35 MPa) as compared to Rurikfjellet formation (3.96-5.53 MPa). Estimation of tensile strength for a cap rock can be very important aspect, especially when it is subjected to a fluid injection into a subsurface reservoir. The information of tensile strength can be used to avoid hydraulic fracturing caused by fluid injection, also fracture propagation and its nature can be determined. Uniaxial compressive strength test is also performed on a set of six plugs. Four of the plugs were tested from Rurikfjellet Formation (depth range 308.00 to 369.53 m) and two plugs were tested from Agardhfjellet Formation (depth range 425.28 to 428.28 m). Most of the tested plugs were failed within the time frame mentioned in ASTM standards for UCS test and few of the plugs show very clear shear failure. Mainly geomechanical parameters [uniaxial compressive strength (σ), Young s modulus (E) for axial deformation] and P- and S-wave velocities are measured from this test. Variations of these all three measurements are analyzed within each formation and also compared with each other. Agardhfjellet Formation has highest values in these measurements as compared to Rurikfjellet Formation. Index test from UCS can be utilized to estimate overburden pressure of rocks and behavior of material when it is subjected to compression in uniaxial directions. Furthermore this data can be used for various modelling of the caprock/seal evaluation. Finally results from Brazilian and uniaxial compressive strength test are compared with previous work performed at NGI. The previous work of NGI was done on core samples from wells Dh-2, Dh-4 and Dh-6 from different formations, also including Rurikfjellet and Agardhfjellet formations at different depths. Results from this study from similar depth are matching with previous results. The overall rock strengths (UCS and tensile strength) are higher at deeper intervals. Reasons can be the compaction, cementation, etc. For more accurate and better understandings of caprock integrity to ensure safe CO2 storage, further research is required than this study. For instance, more core samples should be tested from Agardhfjellet formation because in this study only two were tested and both are very different in all reported parameters. Therefore, evaluation of an entire formation would not be appropriate on the basis of few tested samples. Fracture analysis could be done for both macro and micro levels but it was not considered here due to limited data sources, laboratory facilities and time constraint, though it is highly recommended and can be very useful for the leakage risk assessment in the caprock. Master Thesis Longyearbyen Svalbard UNIS Universitet i Oslo: Digitale utgivelser ved UiO (DUO) Agardhfjellet ENVELOPE(18.833,18.833,78.083,78.083) Longyearbyen Norway Rurikfjellet ENVELOPE(18.217,18.217,77.983,77.983) Svalbard

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