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First EAGE CO2 Geological Storage Workshop
- Conference date: 29 Sep 2008 - 30 Sep 2008
- Location: Budapest, Hungary
- ISBN: 978-94-6282-052-4
- Published: 29 September 2008
1 - 20 of 38 results
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Geological Storage Options in Peri-Mediterranean Countries - Plans for Case Studies
Authors B. Saftic, R. Martinez, F. Donda, M. Car, M.A. Zapatero, I. Suarez, M. Vellico, S. Persoglia, I. Kolenkovic and D. VulinRegional estimates of geological storage capacity included integration of knowledge on the subsurface with a unified way of calculating the capacity in HC fields, regional saline aquifers (basin-wide sedimentary bodies saturated with brine) and coal beds. One way to calculate the effective storage capacity was agreed upon as an attempt to accommodate for highly differentiated geological conditions and assumptions that had to be taken due to scarce data. In the main sedimentary basins of Spain there is a high potential for CO2 storage and another opportunity is seen in ECBM development in the NW coal basins. In Italian sedimentary basins with different geological composition country-wide estimates still have to be made. However, depleted oil fields offer an opportunity to plan pilot injections. In Slovenia, potential storage locations in aquifers have been found, some with significant estimated storage potential but with very few reliable subsurface data. Potential storage in unmineable coal layers deserves therefore additional attention. As for Croatia, a history of O&G industry and resulting data, combined with relatively favourable natural conditions enabled estimates of significant capacity in the SW part of the Pannonian basin, and likely also in the Northern Adriatic off-shore.
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A 3D Geological Model for Site Selection and Characterization in the Paris Basin
Authors S. Grataloup, I. Thinon, P. Houel, J. Delmas, A. Dufournet and P. RenouxPICOREF (Pilote pour l'Injection de CO2 dans les Réservoirs géologiques perméables, En France, 2006-2008) is a R&D project supported by the French National Research Agency and by a consortium of French companies, research institutions and academic laboratories. This project aimed, in particular, at developing a methodology for site selection and characterization in deep saline aquifers for CO2 geological storage. In the Paris basin, two saline aquifers are considered to be potential candidates for CO2 geological storage: Dogger limestones and Triassic sandstones. Geological investigations were conducted to characterize these target aquifers. They mainly consist of: - wells interpretation to identify geological and hydrogeological units, - the reprocessing and interpretation of additionnal seismic lines to characterize the geometry of the geological formations, - fault network updating. These studies provided data for the construction of a 3D geometric model (about 90 x 90 km²), which was built from Trias base up to topographic surface. Main geological and hydrogeological units were considered. This 3D model was then used in the process of site selection by providing thickness maps and for CO2 injection simulations by giving 3D geometry of the main considered surfaces.
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Geological Storage and Mineral Trapping of Industrial CO2 Emissions - Prospects in the Baltic Region
Authors A. Shogenova, S. Sliaupa, K. Shogenov, R. Sliaupiene, R. Pomeranceva, M. Uibu and R. KuusikEstonia, Latvia and Lithuania have strong economic links and coordinated environmental policy. They are situated within common Baltic Sedimentary basin. The smallest of the three countries Estonia with 1.3 mln population produces the highest CO2 emissions mainly due to oil shale used for energy production. Geological conditions in three countries are different, resulting in zero potential for CO2 geological storage (CGS) in Estonia located at the shallowest part of the Baltic sedimentary basin, low CGS potential in Lithuania located at the deepest part of the basin and high CGS potential of Latvia containing large uplifts as the potential traps for CO2 storage. Alternative approaches are suggested for Estonia and Lithuania, focusing on the mineral trapping of CO2. The immobilization of CO2 by the alkaline watered ash and ash transportation water from flue gas formed by shale combustion is a prospective option in Estonia. The serpentinites abundant in the crystalline basement is a prospective rock media for CO2 immobilization in Lithuania. The other CGS option for Estonia and Lithuania is a transportation of CO2 to the Latvian structural traps. Solubility and mineral trapping in the Baltic saline aquifers have large potential which could be considered for future decades.
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CO2 Storage Potential in Poland
By A WójcickiCO2 storage potential of Poland is presented in relation to country emissions and possible future demands of country energy industry in case CO2 geological storage is assumed as a viable option on CO2 emission reduction in not too distant future. The study presents results of PBG's work in EU FP6 CASTOR WP1.2 and EU GeoCapacity projects. Major industrial emission sources in the country are characterised. Storage capacities in case of aquifers, hydrocarbon fields and coal fields are presented and discussed. Storages and related formations are mapped in order to match them with CO2 industrial sources. Possible industrial applications of all three storage options are discussed. In the most pesismistic scenario the storage potential is sufficient for thirty-forty year present day emissions of power and CHP plants in Poland.
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Estimation of CO2 Storage Capacity in South Part of Iran
By A.M. EslamiIran, with a record of over one century of oil production, is currently one of the major oil producing countries of the world. Several of the old fields have been depleted to an uneconomical level of production which requires significant amount of natural gas for re-injection so that currently over 100 million cubic meters of natural gas is re-injected daily to maintain or enhance oil production to an economical level. It is estimated that in order to maintain oil production, over 200 million cubic meters of natural gas will be needed daily by 2015. However, due to the increased level of domestic and export demands for natural gas, IOR, EOR with natural gas is prohibitive and therefore portions of this amount of natural gas can be substituted by carbon dioxide. In the other hand, CO2 emission increased from 240 MM ton per year in 1994 to 382 MM Ton in 2006 which 40% of this emission is related with stationary sources like power plants and industries. According to the fact that part of CO2 can be remain in reservoir in IOR/EOR projects. The CO2 storage capacity was studied for IOR/EOR project in Iran. 20 main mature oil fields were considered and so many factors same as reservoir pressure, temperature, depth, geological condition, exist faults, crude density, crude viscosity and crude composition were considered at first step. Then suitable reservoirs have been chosen. In the case of Oil and gas reservoirs, the fundamental assumption is that the volume previously occupied by the produced hydrocarbon becomes, by and large, available for CO2 storage. Consistent with the resource- reserves pyramid concept, both theoretical and effective CO2 storage capacities are calculated according to formation volume factor, reservoir area, thickness, porosity and water saturation. Water saturation changes that can affect storage capacity, was simulated by formula obtained from laboratory test in carbonated reservoir and according to oil displacement. Conclusion illustrates that more than 16 Giga ton CO2 equivalent 20 years current annual emission of Iran power plants, can be stored in selected reservoir in south of Iran.
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Computing the Permeability Due to the Small Fracturation of a Stratified Rock Mass
By X. RachezThe Dogger limestones in Paris Basin are one of the potential candidates for hosting the first CO2 geological storage in France. The permeability of these carboneous rocks measured on laboratory specimens are generally low and do not represent the permeabilities at a larger size, obtained during geothermal or hydrocarbon exploitations. Fracturation is responsible, partly or even in totality, for these differences. Our task was to demonstrate that it was possible to calculate the permeability « at large » of the small fracturation of the Dogger, in order to give input data adapted to the size of the meshes of equivalent continuous models simulating CO2 injection in the target aquifer. We proposed a conceptual model of the stratified fractured rock mass, made of regularly 3m spaced stratification horizontal joints and four sets of statistical sub-vertical fractures. We simulated the 3D fractures network and computed the permeability due to the small fracturation with a Discrete Fracture Network approach. A parametric study showed the great importance of the horizontal stratification joints and of the longest sub-vertical fractures that cross many stratification beds on the global flow behaviour of the fractured rock mass.
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Knowledge Issues for Automatic Identification of CO2 Storage Sites by Means of Semantic Web Technology
Authors M. Perrin, P. Durville, S. Grataloup, L. Mastella, J. Lions, O. Morel and J.F. RainaudThe present paper proposes a new methodology for identifying and exploiting through internet various documentary sources, that may be relevant for CO2 storage sites. It describes a knowledge communication scenario resting on a software platform, which enables communication and cooperation between various internet services. Several knowledge communication issues are examined such as vocabulary extraction from texts or maps geographical area identification, semantic analysis of geological terms. The proposed solution rests on the definition of adequate domain ontologies and on semantic annotation. It has the advantage of allowing a goal-oriented and largely automated document search.
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Baseline Investigations and Monitoring Strategy at the Vedsted Geological Storage Structure, Northern Jutland, Denmark
By AT SørensenVattenfall A/S in Denmark is developing a project for Carbon Capture and Storage in the Northern part of Denmark. The project consists of a full scale carbon capture plant at power plant Nordjyllandsværket near Aalborg. The CO2 storage facilities are situated only 30 km West of Aalborg - The Vedsted structure. The target storage reservoirs are shoreface sandstones from the Upper Triassic – Lower Jurassic of the Gassum Formation, and the Middle Jurassic fluvial sandstones of the Haldager Formation. The need for storage is expected to be 1,8 million tons of CO2 per year and risk quantification and evaluation will inevitably be a major issue. It is therefore necessary to develop a monitoring investigation strategy which shall be scientifically sound while also being commercially viable. The primary purpose of monitoring CO2 distribution is to provide assurance that CO2 storage is successfully and safely stored, and does not create local HSE problems. The monitoring is also used evaluating the utilization efficiency of a storage reservoir and calibrating and confirming reservoir models.
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Planning Time-lapse CSEM-surveys for Joint Seismic-EM Monitoring of Geological Carbon Dioxide Injection
Authors T. Norman, H. Alnes, O. Christensen, J.J. Zach, O. Eiken and E. TjålandUsing state of the art survey planning and modeling tools, we investigate the possibility of employing marine controlled-source electromagnetic (CSEM) surveys in the monitoring of carbon dioxide sequestration. As a site example, we use the CO2 injection from the Sleipner Øst gas field into the Utsira formation in the North Sea. The injection plume inferred from 3D seismic surveys is used, together with well information and a priori geological knowledge, to build resistivity models for CSEM modeling. We find that the time-lapse change in the CSEM response would have been well above CSEM-acquisition noise levels in both 2001 and 2006. The combination of CSEM and seismic methods, which have a complementary dependence of their response on residual brine saturation, can yield an improved resolution of the CO2-distribution. In addition, CSEM methods are sensitive to the bulk volume of a resistor, also complementary to the superior resolution in seismics. We therefore would expect CSEM monitoring to become a valuable addition to the current monitoring program.
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The Effect of Corrugated Lime-Stone and the Changing of the Near Surface Conditions on CO2 Monitoring Program at Naylor-1, CO2CRC Otway Project, Victoria, Australia
Authors Y.Y.M. Al-Jabri, M. Urosevic and A. KepicThis paper will address these problems and show that by simulating the existing seismic data using synthetic differenced forward modelling, and then comparing the result with field data, improvements can be made in the seismic image of time-lapse data. The results of this work may impact on other areas not associated with CO2 sequestration, such as imaging oil production over areas where producing fields suffer from having a karst topography, such as in the Middle East and Australia.
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Impact of Fractures on CO2 Storage Monitoring - An Integrated Approach
Authors N. Dubos-Sallée, M. Becquey, C. Putot, P.N.J. Rasolofosaon and B. ZinsznerThe monitoring of CO2 storage in fractured reservoirs (depleted hydrocarbon field or brine aquifers) requires the study of the impact of fracturation and fluid substitution on seismic data. Seismic data can provide information about the additional compliance due to the fractures and to the fluids through the analysis of seismic azimuthal anisotropy and the introduction of a rock physics model providing a realistic description of fractured media (where porosity, multiphasic fluid phases, inherent seismic anisotropy, the presence of multiple sets of fractures and their connection with porosity can be considered). Seismic methods by themselves cannot fully describe fracturation and must be associated with other methods through an integrated approach. First, borehole and outcrop geological information can give the upper limit of the fracture density expected at depth in the same formation. Second, rock mechanics helps understanding the fracturation state at depth.
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Monitoring Sleipner CO2 Injection with Combined Surface Seismic and Gravity Data
Authors O. Eiken, H. Alnes and J. LippardTen million tonnes of CO2 have been injected into Utsira Fm. at the Sleipner field since 1996. The site has been regularly monitored by 4D seismic and gravity data, and these have revealed the geometry and volume of the plume. Five vintages of seismic data show bright CO2 reflections and clear time-delay below the plume. Most of the CO2 is still accumulating at lower levels, and only 4% had reached the top of the Utsira Fm. by 2006. The plume is extending NNE-SSW, following the topography of the topmost sand. Some smaller amount has passed a spill point of the primary anticline, and started to fill the next anticline to the north. Best estimate of average density is 760 kg/m3, suggesting that the CO2 is in dense phase in the reservoir. Estimated lower density and higher temperature near the well perforation suggest significant spatial gradients. There are no indications of leakage of CO2 into the overburden shales.
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First Numerical ERT Models for CO2 Plumes in Saline Reservoir with Diverse Crosshole Configurations
More LessElectrical resistivity tomography ERT survey performance in boreholes BRT is studied by numerical forward and inverse simulations to test its sensitivity to changes induced by CO2 injection and migration. Compared with seismic, BRT has lower resolution, but its permanent installation and continuous time-lapse monitoring make it an economical alternative. ERT applications in CO2 storage in saline aquifers are powerful in quantifying intrinsic property changes with time due to the strong contrast between resistive (supercritical) CO2 and conductive saline water reservoir. The resolution of ERT-time lapses is enhanced by applying a constrained inversion with exact apriori geological/structural information on the subsurface from seismic and log data. Our numerical 2D and 3D modelling reveals the capability of BRT techniques to map CO2 plumes and changes as a function of thickness, concentration and electrode configuration as well as modelling and inversion constraints. Some configurations are more favoured due to their better spatial resolution and lower artefacts.
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Surface Reservoir Monitoring for CO2 Sequestration Using Radar Satellites
Authors A. Arnaud, J. Granda and G. CooksleyInSAR (Interferometry for Synthetic Aperture Radar) technology is a spaceborne measurement method, able to detect ground motion with millimetric exactness using radar satellite images. For CO2 sequestration, ground surface monitoring contributes to storage safety and a better understanding of the CO2 distribution inside the reservoir. Thanks to its accuracy, InSAR can contribute to an evaluation of the storage stability, since millimetric surface uplift could be one of the indicators for a potential storage leak. In addition, the large surface of survey provided by radar satellites, combined with the absence of maintenance of instrumentation make InSAR a very reliable and cost effective monitoring tool for long term CO2 storage.
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An Airborne Integrated System to Monitor CO2 Emissions – Preliminary Results in the Adriatic Seashore
Authors M. Vellico, P. Sterzai, N. Creati, F. Coren, R. Vidmar and S. PersogliaCO2 emissions monitoring is one of the rising problems in a CO2 underground storage site. In this framework OGS has tested a simple methodology addressed to control the hypothetic CO2 emissions from an underground storage facility by direct airborne measurements. The study also investigates the economical aspects of such an activity. The test has been carried out using a low cost single engine IFR certified aircraft where an air sampling system, able to measure the CO2 concentration in the air, has been mounted on; a pseudo regular flight pattern has been adopted at an altitude of 2000 ft above the studied area, located in the North Eastern part of the Adriatic seashore and including some small dimension towns. In real time the system collected the position of the aircraft, the air pressure, temperature, relative humidity, wind direction and CO2 concentration values. A specific approach for data reduction to a "datum" altitude has been investigated and successfully applied. The trend of anthropic CO2 concentration has been studied, as the base for the computation of a first primitive diffusive model of CO2 flux in the air and nearby the ground. The test demonstrated the feasibility of the method.
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Modeling of CO2 Sequestration in Coal from Nanoscale to Macroscale
Authors T.J. Tambach, F. van Bergen and H. PagnierWe carried out simulations of CO2 sequestration in coal on a macroscale and nanoscale for improving our insights of gas diffusion in the coal.
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Effects of Capillarity and Solubility in Brine on CO2 Injectivity into an Aquifer
More LessThis study aims to investigate the effects of the capillary and solubility characteristics of the CO2-brine-rock systems on CO2 injectivity and storage capacity numerically. The general-purpose numerical simulator for multicomponent, multiphase fluid flow, TOUGH2 is used as numerical tool. The EOS module, ECO2N which considers the fluid system consisting of CO2 and brine is incorporated to TOUGH2 for the dynamic phase changes during the transport. A generic axissymmetric 2D aquifer model is created. Two distinct capillary pressure models are used. A CO2 injection rate of 60 kg/s is assured in three injection blocks from the bottom of the model. Due to the high solubility of CO2 into brine, the effect of the capillary forces on injectivity is determined to be less pronounced compared to inert gases. Another important effect of the solubility is on the critical gas saturation which decreases below the determined values of relative permeability curves. The increasing salinity of the aquifer brine increases the effect of the capillary forces on the injectivity. Because of the salting out effect less amount of CO2 dissolves in the brine. The salt precipitation is found to be another factor influencing the injectivity negatively.
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The Effects of Geomechanical Deformation on Seismic Monitoring of CO2 Sequestration
Authors J. Verdon, D.A. Angus, J.M. Kendall, J. Segura, S. Skachkov and Q.J. FisherWhen CO2 is injected into the subsurface, changes in pore pressure may lead to deformation of both the reservoir and the subsurface. Of concern is that this deformation may create or reactivate fracture networks, providing pathways for CO2 to migrate away from the targeted zone. By coupling a commercial reservoir fluid flow simulator with a finite element geomechanical solver, we model the geomechanical effects of CO2 injection into a simple reservoir. In order to link deformation with changes in seismic observables, a stress dependent rock physics model is outlined and calibrated. We utilize this model to show how injection induced stress changes might be imaged using shear wave splitting.
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Managing Over-pressure in Deep Saline Aquifer Storage of CO2
Authors M. Carpenter, T.A. Flach and S. SolomonOne of the main challenges facing industrial scale storage of CO2 in saline aquifers will likely arise from pressure build up in the storage formation and displacement of brine. The study presented here examines two mitigation strategies for limiting the rate and magnitude of over-pressure development by producing and re-circulating brine in the storage system. The analysis is performed using a reservoir modelling tool applied to a multi-aquifer storage system.
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Keynote: The Study of CO2 Natural Reservoirs to Develop Criteria for Risk Assessment and Safety Strategy
By S. LombardiThe potential for leakage from a man-made CO2 geological storage reservoir has received much recent attention, as concern has been voiced by governments, environmental NGO's, and the general public regarding possible risks involved in this global warming mitigation strategy. Despite the fact that most scientists working in this field consider carbon capture and storage (CCS) to be a realistic and safe approach to decreasing man-made greenhouse gas emissions while, at the same time, minimising impact on world-wide economic development, a lack of public support could potentially block the wide-spread implementation of this very promising technology. As such it is critical that we in the research and development community take on the challenge of understanding gas migration mechanisms and the potential for leakage (where, over what time scale, and how much). Only by facing this issue directly will we be able to assure the public that: i) scientific knowledge exists to choose the best and safest sites, ii) techniques and approaches have been developed to monitor the safety of these sites during the operational and post-injection phases; and iii) strategies and technologies exist should remediation action be required. In other words, to show that all potential risks have been examined and minimised.
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