Relevant bibliographies by topics / CO2 geosequestration

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers

Academic literature on the topic 'CO2 geosequestration'

Author: Grafiati
Published: 7 September 2023

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Journal articles on the topic "CO2 geosequestration"

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Taggart, Ian. "Extraction of Dissolved Methane in Brines by CO2 Injection: Implication for CO2 Sequestration." SPE Reservoir Evaluation & Engineering 13, no. 05 (October 11, 2010): 791–804. http://dx.doi.org/10.2118/124630-pa.

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Summary The solubility of carbon dioxide (CO2) in underground saline formations is considered to offer significant long-term storage capability to effectively sequester large amounts of anthropogenic CO2. Unlike enhanced oil recovery (EOR), geosequestration relies on longer time scales and involves significantly greater volumes of CO2. Many geosequestration studies assume that the initial brine state is one containing no dissolved hydrocarbons and, therefore, apply simplistic two-component solubility models starting from a zero dissolved-gas state. Many brine formations near hydrocarbons, however, tend to be close to saturation by methane (CH4). The introduction of excess CO2 in such systems results in an extraction of the CH4 into the CO2-rich phase, which, in turn, has implications for monitoring of any sequestration project and offers the possibly additional CH4 mobilization and recovery.
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Sarkarfarshi, Mirhamed, Farshad A. Malekzadeh, Robert Gracie, and Maurice B. Dusseault. "Parametric sensitivity analysis for CO2 geosequestration." International Journal of Greenhouse Gas Control 23 (April 2014): 61–71. http://dx.doi.org/10.1016/j.ijggc.2014.02.003.

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Sharma, S., P. Cook, T. Berly, and C. Anderson. "AUSTRALIA’S FIRST GEOSEQUESTRATION DEMONSTRATION PROJECT—THE CO2CRC OTWAY BASIN PILOT PROJECT." APPEA Journal 47, no. 1 (2007): 259. http://dx.doi.org/10.1071/aj06017.

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Geological sequestration is a promising technology for reducing atmospheric emissions of carbon dioxide (CO2) with the potential to geologically store a significant proportion Australia of Australia’s stationary CO2 emissions. Stationary emissions comprise almost 50% (or about 280 million tonnes of CO2 per annum) of Australia’s total greenhouse gas emissions. Australia has abundant coal and gas resources and extensive geological storage opportunities; it is therefore well positioned to include geosequestration as an important part of its portfolio of greenhouse gas emission mitigation technologies.The Cooperative Research Centre for Greenhouse Gas Technologies is undertaking a geosequestration demonstration project in the Otway Basin of southwest Victoria, with injection of CO2 planned to commence around mid 2007. The project will extract natural gas containing a high percentage of CO2 from an existing gas well and inject it into a nearby depleted natural gas field for long-term storage. The suitability of the storage site has been assessed through a comprehensive risk assessment process. About 100,000 tonnes of CO2 is expected to be injected through a new injection well during a one- to two-year period. The injection of CO2 will be accompanied by a comprehensive monitoring and verification program to understand the behaviour of the CO2 in the subsurface and determine if the injected carbon dioxide has migrated out of the storage reservoir into overlying formations. This project will be the first storage project in Australia and the first in the world to test monitoring for storage in a depleted gas reservoir. Baseline data pertinent to geosequestration is already being acquired through the project and the research will enable a better understanding of long-term reactive transport and trapping mechanisms.This project is being authorised under the Petroleum Act 1998 (Victoria) and research, development and demonstration provisions administered by the Environment Protection Authority (EPA) Victoria in the absence of geosequestration- specific legislation. This highlights the need for such legislation to enable commercial-scale projects to proceed. Community acceptance is a key objective for the project and a consultation plan based on social research has been put in place to gauge public understanding and build support for the technology as a viable mitigation mechanism.
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LEUNING, R., D. ETHERIDGE, A. LUHAR, and B. DUNSE. "Atmospheric monitoring and verification technologies for CO2 geosequestration." International Journal of Greenhouse Gas Control 2, no. 3 (July 2008): 401–14. http://dx.doi.org/10.1016/j.ijggc.2008.01.002.

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Sharma, Sandeep, Peter Cook, and Charles Jenkins. "Demonstrating geosequestration in Australia: the CO2CRC Otway Project." APPEA Journal 49, no. 2 (2009): 601. http://dx.doi.org/10.1071/aj08074.

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The CO2CRC has a demonstration storage project underway in the Otway Basin of southwest Victoria. The aim of the project is to demonstrate that carbon capture and storage (CCS) can be performed under Australian conditions. The project involves extracting CO2 rich gas from an existing field and injecting it into a nearby depleted natural gas field for long-term storage. Injection commenced in April 2008, and approximately 100,000 tonnes of CO2 are planned to be injected through a new injection well drilled in 2007. A multi-disciplinary monitoring and verification (M&V) program has been in place from late 2005 and a baseline state of the subsurface, near surface and atmospheric conditions has been comprehensively defined prior to the commencement of injection. The project has also been instrumental in unravelling the legislative overlaps between jurisdictions and has helped shape the regulatory regime being developed by the Victorian Government. At the present time over 35,000 tonnes of CO2 has been injected and a variety of monitoring data collected. This paper aims to provide an update on the holistic project and how some of the findings may lead to expediting commercial uptake of CCS in Australia.
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Myers, Matthew, Linda Stalker, Bobby Pejcic, and Andrew Ross. "Tracers – Past, present and future applications in CO2 geosequestration." Applied Geochemistry 30 (March 2013): 125–35. http://dx.doi.org/10.1016/j.apgeochem.2012.06.001.

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Urosevic, M., R. Pevzner, B. Gurevich, V. Shulakova, A. Kepic, and S. Sharma. "Seismic monitoring of CO2 geosequestration: CO2CRC Otway project case study." ASEG Extended Abstracts 2010, no. 1 (December 2010): 1. http://dx.doi.org/10.1081/22020586.2010.12042023.

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Liang, Yunfeng, Shinya Tsuji, Jihui Jia, Takeshi Tsuji, and Toshifumi Matsuoka. "Modeling CO2–Water–Mineral Wettability and Mineralization for Carbon Geosequestration." Accounts of Chemical Research 50, no. 7 (June 29, 2017): 1530–40. http://dx.doi.org/10.1021/acs.accounts.7b00049.

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Damico, James R., Robert W. Ritzi, Naum I. Gershenzon, and Roland T. Okwen. "Challenging Geostatistical Methods To Represent Heterogeneity in CO2 Reservoirs Under Residual Trapping." Environmental and Engineering Geoscience 24, no. 4 (December 21, 2018): 357–73. http://dx.doi.org/10.2113/eeg-2116.

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Abstract Geostatistical methods based on two-point spatial-bivariate statistics have been used to model heterogeneity within computational studies of the dispersion of contaminants in groundwater reservoirs and the trapping of CO2 in geosequestration reservoirs. The ability of these methods to represent fluvial architecture, commonly occurring in such reservoirs, has been questioned. We challenged a widely used two-point spatial-bivariate statistical method to represent fluvial heterogeneity in the context of representing how reservoir heterogeneity affects residual trapping of CO2 injected for geosequestration. A more rigorous model for fluvial architecture was used as the benchmark in these studies. Both the geostatistically generated model and the benchmark model were interrogated, and metrics for the connectivity of high-permeability preferential flow pathways were quantified. Computational simulations of CO2 injection were performed, and metrics for CO2 dynamics and trapping were quantified. All metrics were similar between the two models. The percentage of high-permeability cells in spanning connected clusters (percolating clusters) was similar because percolation is strongly dependent upon proportions, and the same proportion of higher permeability cross-strata was specified in generating both models. The CO2 plume dynamics and residual trapping metrics were similar because they are largely controlled by the occurrence of percolating clusters. The benchmark model represented more features of the fluvial architecture and, depending on context, representing those features may be quite important, but the simpler geostatistical model was able to adequately represent fluvial reservoir architecture within the context and within the scope of the parameters represented here.
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Faiz, M. M., S. A. Barclay, N. Sherwood, L. Stalker, A. Saghafi, and D. J. Whitford. "NATURAL ACCUMULATION OF CO2 IN COALS FROM THE SOUTHERN SYDNEY BASIN—IMPLICATIONS FOR GEOSEQUESTRATION." APPEA Journal 46, no. 1 (2006): 455. http://dx.doi.org/10.1071/aj05027.

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The southern Sydney Basin is an ideal natural analogue for CO2 geosequestration because of the widespread CO2 occurrence, extensive data sets available and general knowledge of gas distribution. The CO2 mainly occurs adsorbed in coal, incorporated into carbonate minerals and dissolved in formation water. On this basis, an area of ~900 km2 has been chosen for detailed examination.Gas in the coal seams of this area contain mainly CH4 and CO2, the CO2 content ranging from Calculations indicate that about 78 x 106 tonnes of CO2 are presently stored in coaly intervals in the study area. Assuming a storage capacity of 20 m3/t for these coal seams, the total CO2 storage capacity for the coaly intervals is ~880 x 106 tonnes. Using the study area as an analogue for enhanced coal seam methane production, 175 x 106 tonnes of CO2 could be stored, assuming a 50% CH4 recovery factor and an average CO2 sorption capacity 1.5 times that for CH4.
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Dissertations / Theses on the topic "CO2 geosequestration"

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Popik, Dmitry. "Advanced Analysis of Time-lapse Seismic Data for CO2 Geosequestration Monitoring." Thesis, Curtin University, 2019. http://hdl.handle.net/20.500.11937/75808.

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This thesis addresses challenges of land time-lapse (4D) surface seismic data analysis for monitoring of CO2 geosequstration. The approach includes development of an optimal seismic acquisition strategy, seismic forward modelling workflow, model-guided processing and imaging of the 4D seismic data for structural and quantitative interpretation. Successful onshore seismic monitoring is achieved using buried geophone array and purposefully designed processing flow with tracking of 4D signal and noise at each processing stage.
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Popik, Sofya. "Integration of Borehole and Surface Seismic Monitoring Techniques in CO2 Geosequestration Projects." Thesis, Curtin University, 2021. http://hdl.handle.net/20.500.11937/88349.

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This thesis is focused on utilisation of both borehole and surface seismic techniques to improve monitoring effectiveness in CO2 geosequestration projects based on data acquired within the CO2CRC Otway Project. The study includes processing and analysis of 4D surface seismic data with buried receiver array, investigation of optimal source effort required to image time-lapse anomaly, and analysis of multiple 3D VSP datasets for the purpose of building anisotropic velocity model of the Otway Site.
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Alonaizi, Faisal. "Application of diffracted wave analysis to time-lapse seismic monitoring of CO2 geosequestration." Thesis, Curtin University, 2014. http://hdl.handle.net/20.500.11937/1257.

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Successful implementation of carbon capture and sequestration technology requires monitoring techniques for tracking CO2 plume evolution in the subsurface and early leakage detection. Application of time-lapse seismic data for these purposes can often be challenging in low signal/noise ratio conditions. The research is focussed on developing a robust seismic imaging algorithm for CO2 geosequestration monitoring, based on diffracted waves analysis. The algorithm is tested on several datasets, including CO2CRC Otway project time-lapse seismic data.
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dos, Santos Maia Correa Julia. "Distributed Acoustic Sensing for Seismic Imaging and Reservoir Monitoring Applied to CO2 Geosequestration." Thesis, Curtin University, 2018. http://hdl.handle.net/20.500.11937/75668.

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The thesis is focused on the evaluation of distributed acoustic sensing (DAS) technique applied to seismic imaging and monitoring of CO2 geosequestration. It utilises the data acquired at the CO2CRC Otway site (Victoria) and the National Geosequestration Laboratory (Western Australia) to explore capabilities of the sensing technique, optimise data acquisition and processing, and compare it to other seismic sensors. Surface and downhole acquisition geometries and a range of fibre optic cables and deployment techniques were considered.
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Cai, Mosi, and 蔡默西. "An Assessment on CO2 Geosequestration Systems in the Taihsi Basin, Central Taiwan." Thesis, 2016. http://ndltd.ncl.edu.tw/handle/11925449480433640271.

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碩士
國立中央大學
地球科學學系
104
Geological storage of carbon dioxide (CO2) is to inject and store a large amount of anthropogenic CO2 in deep and sealed porous rocks in order to mitigate the aggravated threat of global warning. Borehole data are used to understand the spatial distribution of suitable CO2 reservoirs and cap rocks in the Taihsi Basin, central Taiwan, where the level of seismicity is low. Spatial distribution of formation thickness and depth for CO2 reservoirs and cap rocks indicates three CO2 storage systems existed in the study area. They are: (1) late Miocene to Pliocene Nanchuang Formation and Kueichulin Formation (reservoirs)-Chinshui Shale (cap rocks) system (hereafter abbreviated as NK-C system), (2) early to middle Miocene Shihti Formation and Peiliao Formation (reservoirs)-Talu Shale (cap rocks) system (SP-T system), (3) late Oligocene to early Miocene Wuchishan Formation and Mushan Formation (reservoirs)-Piling Shale (cap rocks) system (WM-P system). According to distributions of depth for reservoirs and cap rocks, we assess appropriate areas for CO2 storage. Depth of reservoirs for NK-C system in the west of the study area, and depth of reservoirs for SP-T system offshore Mai-liao power plant is shallower than 800 m which are not suitable for CO2 storage. North of the study area and close to the Wu River, reservoirs for WM-P system and SP-T system reach a depth more than 3000 m, a depth too deep for storing CO2 economically. The areas mentioned foregoing are not suitable for CO2 storage, and others are applicable. However, for NK-C system, the cap rocks (i.e. the Chinshui Shale) become sand-prone due to facies changes, leading to fail to retard great amounts of CO2 underground in the south of Chang-Bin Site. There are four sites (Taichung Power Plant Site, Chang-Bin Site, Wong-gong Site and Mai-Liao Power Plant Site from north to south) considerably suitable to retard CO2 underground. Taichung Power Plant Site is suitable for NK-C system, Chang-Bin Site is suitable for SP-T system, Mai-Liao Power Plant Site is suitable for SP-T system and Wong-gong site is most prominent which can be applied to more storage system (SP-T and WM-P system). By USDOE assessment, calculated results of storage resource for CO2 show that total storage resource is about 3.54Gt, 2.71Gt and 5.82Gt for NK-C system, SP-T system and M-P system respectively.
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Books on the topic "CO2 geosequestration"

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Experimental Study Of Multiphase Flow In Porous Media During Co2 Geosequestration Processes. Springer, 2012.

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Cook, Peter, ed. Geologically Storing Carbon. CSIRO Publishing, 2014. http://dx.doi.org/10.1071/9781486302314.

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Carbon capture and geological storage (CCS) is presently the only way that we can make deep cuts in emissions from fossil fuel-based, large-scale sources of CO2 such as power stations and industrial plants. But if this technology is to be acceptable to the community, it is essential that it is credibly demonstrated by world-class scientists and engineers in an open and transparent manner at a commercially significant scale. The aim of the Otway Project was to do just this. Geologically Storing Carbon provides a detailed account of the CO2CRC Otway Project, one of the most comprehensive demonstrations of the deep geological storage or geosequestration of carbon dioxide undertaken anywhere. This book of 18 comprehensive chapters written by leading experts in the field is concerned with outstanding science, but it is not just a collection of scientific papers – it is about 'learning by doing'. For example, it explains how the project was organised, managed, funded and constructed, as well as the approach taken to community issues, regulations and approvals. It also describes how to understand the site: Are the rocks mechanically suitable? Will the CO2 leak? Is there enough storage capacity? Is monitoring effective? This is the book for geologists, engineers, regulators, project developers, industry, communities or anyone who wants to better understand how a carbon storage project really 'works'. It is also for people concerned with obtaining an in-depth appreciation of one of the key technology options for decreasing greenhouse emissions to the atmosphere.
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Book chapters on the topic "CO2 geosequestration"

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Daley, Thomas M., and William Harbert. "Goals of CO2 Monitoring." In Geophysics and Geosequestration, 54–70. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.004.

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Maxwell, Shawn. "Microseismic Imaging of CO2 Injection." In Geophysics and Geosequestration, 168–80. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.011.

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Halland, Eva K. "Offshore Storage of CO2 in Norway." In Geophysics and Geosequestration, 195–208. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.013.

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Eiken, Ola. "Twenty Years of Monitoring CO2 Injection at Sleipner." In Geophysics and Geosequestration, 209–34. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.014.

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Daley, Thomas M. "Rock Physics of CO2 Storage Monitoring in Porous Media." In Geophysics and Geosequestration, 71–82. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.005.

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Vasco, Donald W., Alessandro Ferretti, Alessio Rucci, Sergey V. Samsonov, and Don White. "Monitoring the Deformation Associated with the Geological Storage of CO2." In Geophysics and Geosequestration, 93–114. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.007.

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Landrø, Martin, and Mark Zumberge. "Estimating Saturation and Density Changes Caused by CO2 Injection at Sleipner." In Geophysics and Geosequestration, 134–53. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.009.

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White, Don. "Integrated Geophysical Characterization and Monitoring at the Aquistore CO2 Storage Site." In Geophysics and Geosequestration, 257–79. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.016.

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Grude, Sissel, and Martin Landrø. "Time-Lapse Seismic Analysis of the CO2 Injection into the Tubåen Formation at Snøhvit." In Geophysics and Geosequestration, 319–38. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.019.

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Davis, Thomas L., Scott Wehner, and Trevor Richards. "Case Studies of the Value of 4D, Multicomponent Seismic Monitoring in CO2 Enhanced Oil Recovery and Geosequestration." In Geophysics and Geosequestration, 235–56. Cambridge University Press, 2019. http://dx.doi.org/10.1017/9781316480724.015.

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Conference papers on the topic "CO2 geosequestration"

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Shulakova, V., M. Urosevic, R. Pevzner, and A. Kepic. "Seismic Monitoring of CO2 Geosequestration in Otway Basin, Australia." In 72nd EAGE Conference and Exhibition incorporating SPE EUROPEC 2010. European Association of Geoscientists & Engineers, 2010. http://dx.doi.org/10.3997/2214-4609.201401121.

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Yurikov, A., K. Tertyshnikov, S. Yavuz, P. Shashkin, R. Isaenkov, E. Sidenko, S. Glubokovskikh, P. Barraclough, and R. Pevzner. "Carbon Geosequestration Monitoring Using Multi-Well DAS VSP: Stage 3 of the CO2CRC Otway project." In EAGE Asia Pacific Workshop on CO2 Geological Storage. European Association of Geoscientists & Engineers, 2022. http://dx.doi.org/10.3997/2214-4609.202275019.

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Zhang*, Yihuai, Maxim Lebedev, Mohammad Sarmadivaleh, Ahmed Barifcani, Hongyan Yu, and Stefan Iglauer. "3D pore scale analysis of limestone matrix dissolution in CO2 EOR and geosequestration." In SEG 2017 Workshop: Carbonate Reservoir E&P Workshop, Chengdu, China, 22-24 October 2017. Society of Exploration Geophysicists, 2017. http://dx.doi.org/10.1190/carbonate2017-05.

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Bona, A., A. Shaiban, R. Pevzner, and M. Urosevic. "Time-lapse Seismic Anisotropy Analysis for CO2 Geosequestration Using 3D 3C VSP Data." In 73rd EAGE Conference and Exhibition incorporating SPE EUROPEC 2011. Netherlands: EAGE Publications BV, 2011. http://dx.doi.org/10.3997/2214-4609.20149202.

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Pevzner, R., S. Glubokovskikh, K. Tertyshnikov, S. Yavuz, A. Egorov, E. Sidenko, S. Popik, et al. "PERMANENT DOWNHOLE SEISMIC MONITORING FOR CO2 GEOSEQUESTRATION: STAGE 3 OF THE CO2CRC OTWAY PROJECT." In APGCE 2019. European Association of Geoscientists & Engineers, 2019. http://dx.doi.org/10.3997/2214-4609.201903366.

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Glubokovskikh, S., R. Pevzner, D. Popik, T. Dance, E. Caspari, V. Shulakova, and B. Gurevich. "Seismic Monitoring of CO2 Geosequestration - CO2CRC Otway Case Study Using Full 4D Elastic Modelling." In 78th EAGE Conference and Exhibition 2016. Netherlands: EAGE Publications BV, 2016. http://dx.doi.org/10.3997/2214-4609.201601316.

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Turkes, Ozan, Ming-Kuo Lee, Jorge Antonio Moncada Vivas, and Carlos Carrero Marquez. "IDENTIFYING THE MINERALOGICAL CHANGES IN SHALE CAPROCKS FROM DEEP CO2 GEOSEQUESTRATION BY USING XRD AND RAMAN SPECTROSCOPY." In 68th Annual GSA Southeastern Section Meeting - 2019. Geological Society of America, 2019. http://dx.doi.org/10.1130/abs/2019se-326819.

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Al-Anssari, Sarmad, Zain-UL-Abedin Arain, Ahmed Barifcani, Alireza Keshavarz, Muhammad Ali, and Stefan Iglauer. "Influence of Pressure and Temperature on CO2-Nanofluid Interfacial Tension: Implication for Enhanced Oil Recovery and Carbon Geosequestration." In Abu Dhabi International Petroleum Exhibition & Conference. Society of Petroleum Engineers, 2018. http://dx.doi.org/10.2118/192964-ms.

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Popik, D., V. Shulakova, K. V. Tertyshnikov, S. Ziramov, M. Urosevic, and R. Pevzner. "Model-guided Processing of Time-lapse Seismic for Real-time Monitoring of CO2 Geosequestration - CO2CRC Otway Project Case Study." In 79th EAGE Conference and Exhibition 2017. Netherlands: EAGE Publications BV, 2017. http://dx.doi.org/10.3997/2214-4609.201701388.

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Ohl, Derek, Abdelmoneam Raef, Lynn Watnef, and Saibal Bhattacharya. "Rock formation characterization for CO2‐EOR and carbon geosequestration; 3D seismic amplitude and coherency anomalies, Wellington Field, Kansas, USA." In SEG Technical Program Expanded Abstracts 2011. Society of Exploration Geophysicists, 2011. http://dx.doi.org/10.1190/1.3627595.

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