CO2 - H2 Optimisation in Rocks for Underground Storage (CHORUS)
Lead Research Organisation:
NATIONAL OCEANOGRAPHY CENTRE
Department Name: Science and Technology
Abstract
The UK is poised to embrace net zero carbon emission technologies to meet its Paris accord targets, by combining an increasing use of the renewables with efficient underground hydrogen storage (UHS) and long-planned Carbon Capture Usage and Storage (CCUS) schemes. This proposal will advance knowledge needed to combine UHS with CCUS (i.e., a win-win strategy), by developing a novel seismic monitoring tool to capture key geophysical properties of the stored hydrogen (H2). Specifically, UHS implies cyclic injection/depletion activities to deal with seasonal fluctuations associated with energy demands. But for the cycle to be successful, a cushion gas is needed to keep the reservoir pressurised. Carbon dioxide (CO2) being an abundant greenhouse gas, is a promising, environmentally friendly alternative. Its use as cushion gas, if successful, could significantly reduce the cost of seasonal H2 retrieval and open up novel research directions.
In most storage projects, fluids injected in geological formations are seismically monitored by associating the variation of seismic velocity and amplitude with fluid content. However, if H2 is injected in a CO2-cushioned reservoir, the similar acoustic properties of both gases together with the short timescales to settle within an injection/extraction cycle obscure the H2 seismic visibility.
CHORUS will test the hypothesis that a viscosity contrast is the key to seismic H2 detectability in a H2-CO2 storage scenario. We propose to test this hypothesis in three stages, using our current expertise with multi-flow laboratory tests, modelling and dispersive wave propagation.
First, we will perform laboratory measurements of the elastic and transport properties of reservoir rocks saturated with the fluids present in UHS applications. We will control these experiments to emulate viscosity contrasts of H2-CO2 at reservoir conditions.
Second, we will apply existing rock physics models established for CCUS to calculate the seismic velocities, attenuation and dispersion of these rocks under different saturation conditions. This will involve reservoir rocks saturated with H2-water and CO2-water below a caprock seal. We will calibrate these models using the novel dataset.
Third, we will scale up our finds by calculating synthetic seismic data corresponding to a vertical seismic profile (time-lapse experiment with attenuation contrast between different fluid regimes) controlled by the viscosity contrast and informed by the experimental data. Using this synthetic dataset, we will conduct a sensitivity analysis to assess the limits of seismic detectability of H2.
Outcomes of this proposal have the potential to de-risk UHS monitoring by enhancing our ability to quantify H2 through better seismic resolution of the H2-CO2 interface. A better understanding of the dispersive properties of H2-saturated rocks will enable policy-makers to identify seismic attributes associated with fracturing and quantifying leakage risk. Altogether will facilitate both the planning of efficient monitoring strategies for industrial seasonal UHS.
We propose to disseminate our results in the form of two (6-monthly) reports, a collaborative scientific publication in a lead academic journal and a conference publication, and openly accessible datasets from the rock physics and the synthetic seismic experiments. Using this project as springboard proof-of-concept, we intend to consolidate its finds by pursuing a long-term UK collaboration through a NERC Pushing Frontiers funding proposal, to include the assessment of caprock integrity by incorporating geomechanical effects from fracturing on seismic signatures. Such a proposal would incorporate fundamental research, as well as detailed anisotropic modelling of fractured top-seal/reservoir and seismic data. In addition, our theoretical advancements can complement ongoing UHS studies, both in NOC (NERC MOET), and UoE (EPSRC HyStorPore) with novel rock physical knowledge.
In most storage projects, fluids injected in geological formations are seismically monitored by associating the variation of seismic velocity and amplitude with fluid content. However, if H2 is injected in a CO2-cushioned reservoir, the similar acoustic properties of both gases together with the short timescales to settle within an injection/extraction cycle obscure the H2 seismic visibility.
CHORUS will test the hypothesis that a viscosity contrast is the key to seismic H2 detectability in a H2-CO2 storage scenario. We propose to test this hypothesis in three stages, using our current expertise with multi-flow laboratory tests, modelling and dispersive wave propagation.
First, we will perform laboratory measurements of the elastic and transport properties of reservoir rocks saturated with the fluids present in UHS applications. We will control these experiments to emulate viscosity contrasts of H2-CO2 at reservoir conditions.
Second, we will apply existing rock physics models established for CCUS to calculate the seismic velocities, attenuation and dispersion of these rocks under different saturation conditions. This will involve reservoir rocks saturated with H2-water and CO2-water below a caprock seal. We will calibrate these models using the novel dataset.
Third, we will scale up our finds by calculating synthetic seismic data corresponding to a vertical seismic profile (time-lapse experiment with attenuation contrast between different fluid regimes) controlled by the viscosity contrast and informed by the experimental data. Using this synthetic dataset, we will conduct a sensitivity analysis to assess the limits of seismic detectability of H2.
Outcomes of this proposal have the potential to de-risk UHS monitoring by enhancing our ability to quantify H2 through better seismic resolution of the H2-CO2 interface. A better understanding of the dispersive properties of H2-saturated rocks will enable policy-makers to identify seismic attributes associated with fracturing and quantifying leakage risk. Altogether will facilitate both the planning of efficient monitoring strategies for industrial seasonal UHS.
We propose to disseminate our results in the form of two (6-monthly) reports, a collaborative scientific publication in a lead academic journal and a conference publication, and openly accessible datasets from the rock physics and the synthetic seismic experiments. Using this project as springboard proof-of-concept, we intend to consolidate its finds by pursuing a long-term UK collaboration through a NERC Pushing Frontiers funding proposal, to include the assessment of caprock integrity by incorporating geomechanical effects from fracturing on seismic signatures. Such a proposal would incorporate fundamental research, as well as detailed anisotropic modelling of fractured top-seal/reservoir and seismic data. In addition, our theoretical advancements can complement ongoing UHS studies, both in NOC (NERC MOET), and UoE (EPSRC HyStorPore) with novel rock physical knowledge.
Title | Geophysical and transport properties of salt rocks subjected to loading/unloading, and during dissolution |
Description | The dataset contains data from a dual experiment conducted to study (i) the stress dependence of ultrasonic (elastic) waves and permeability of salt rocks, and (ii) the dissolution of an intact and a cracked halite samples using geophysical methods. The tests were run in the high-pressure room-temperature (20°C) experimental setup for flow-through tests at the National Oceanography Centre, Southampton (NOCS) (Falcon et al. 2016). The rig consists of a triaxial vessel equipped with (i) ultrasonic sensors that allow measuring P- and S-wave velocities and their attenuation factors using the pulse echo method (McCann and Sothcott, 1992), and (ii) two rigs of electrodes embedded into the rubber sleeve of the pressure vessel for collecting electrical resistivity data that can be used to build up an electrical tomography of the sample (North el al. 2013). The rig has automatic control of both confining and pore pressure (ISCO EX-100D system). For the operating conditions and in homogeneous samples, the bulk electrical resistivity error is <1% for bulk resistivities <100 O m, increasing up to 5% with the degree of heterogeneity and above this resistivity value, at frequencies 1-500 Hz (North et al., 2013). Regarding the ultrasonic data, the technique and instrumentation used in this experiment provide velocity precision of ± 0.1% and accuracy of ± 0.3% (95% confidence), and attenuation accuracy of ± 0.1 dB cm-1 within the frequency range 300-1000 kHz (Best, 1992). The dataset presented here show the ultrasonic data at a single frequency of 600 kHz, obtained from Fourier analysis of broadband signals. Permeability to water and to N2 can be both determined with the aid of integrated flowmeters and pore pressure sensors both up- and downstream of the rock sample. The rock samples include: Pre-Cambrian salt (unknown well, Pakistan (source: www.likit.co.uk/)), Cambrian salt (unknown well, Tunguska Basin, Russia), Triassic salt (Arm Hill #1 well, NW Lancashire, UK), and Messinian salt (3A GN3 S02 well, core # 19, near Marianopoli, Sicily). 2.5 cm length, 5 cm diameter core plugs were extracted from precursor rocks, composition estimated by X-ray diffraction analysis, and connected porosity by He-pycnometry. Falcon-Suarez, I., North, L., Amalokwu, K., Best, A., 2016. Integrated geophysical and hydromechanical assessment for CO2 storage: shallow low permeable reservoir sandstones. Geophysical Prospecting 64, 828-847, http://doi.org/10.1111/1365-2478.12396. McCann, C., Sothcott, J., 1992. Laboratory measurements of the seismic properties of sedimentary rocks. Geological Society, London, Special Publications 65, 285-297, https://doi.org/10.1144/gsl.sp.1992.065.01.22. North, L., Best, A.I., Sothcott, J., MacGregor, L., 2013. Laboratory determination of the full electrical resistivity tensor of heterogeneous carbonate rocks at elevated pressures. Geophysical Prospecting 61, 458-470, https://doi.org/10.1111/j.1365-2478.2012.01113.x. |
Type Of Material | Database/Collection of data |
Year Produced | 2023 |
Provided To Others? | Yes |
Impact | None yet |
URL | https://www2.bgs.ac.uk/nationalgeosciencedatacentre/citedData/catalogue/13c05fe8-0d1d-49e5-b55e-5cf4... |
Description | National Oceanography Centre (NOC) Southampton and the Institute of Energy and Environment of the University of São Paulo (IEE/USP) |
Organisation | Universidade de São Paulo |
Country | Brazil |
Sector | Academic/University |
PI Contribution | Fieldtrip to Parana Basin, Sao Paulo, including sample selection and acquisition Lecture given by the PI (Ismael Himar Falcon Suarez) at the USP in March 2023 Organization of a workshop in the NOC, Southampton (UK) entitled "Research Roadmap for Efficient Underground CO2 and H2 Storage", inviting two members of the Hosting two USP students for two weeks in the NOC X-ray diffraction (mineralogical) analysis from samples collected in the Parana Basin, a reservoir formation targeted for CO2 storage Dataset: NERC EDS National Geoscience Data Centre. (Dataset). https://doi.org/10.5285/256981dc-245b-410a-90a4-5f0138583a65 Paper submitted to JGR Solid Earth |
Collaborator Contribution | Organization of a field trip in Sao Paulo, including sample acquisition, preparation and delivered to NOC in the UK |
Impact | Dataset: Falcon-Suarez, I. & Mondol, N. H. 2024. Effect of porosity and clays on geophysical and transport properties of sandstone exposed to CO2 injection: Influence of rock heterogeneities on CO2 storage monitoring. NERC EDS National Geoscience Data Centre. (Dataset). https://doi.org/10.5285/256981dc-245b-410a-90a4-5f0138583a65 |
Start Year | 2022 |
Description | Invited talk in Nanjing, China (Dec 2023) |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | This event was an SEG workshop entitled "Rock Physics and Geofluid Detection", that took place in Nanjing, China, on the 9-10th Dec 2023. |
Year(s) Of Engagement Activity | 2023 |
URL | https://dxy.hhu.edu.cn/en/2023/1219/c10164a269718/page.htm |
Description | Invited talk in Trondheim, Norway (8-9th May 2023) |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Postgraduate students |
Results and Impact | Invited talk given by the PI (IHFS) in Trondheim, Norway (May 2023), for the annual 2-days seminar of the (NTNU) Research Council and industry funded project entitled GAMES, where the G represents geophysics and the M has to do with Mathematics - The project is led by Martin Landrø. The event includes presentations by the local PhD students and professors involved, plus a few invited external speakers |
Year(s) Of Engagement Activity | 2023 |
Description | Lecture at the University of Turin, Italy (18th July 2023) |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Local |
Primary Audience | Undergraduate students |
Results and Impact | Lecture given by the PI (IHFS) at the Engineering School, University of Turin (Italy) to promote gas storage research among the student community |
Year(s) Of Engagement Activity | 2023 |
URL | https://www.polito.it/en/polito/communication-and-press-office/events/news?idn=21233 |
Description | Oral presentation at the University of Lausanne (5th March 2024) |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Postgraduate students |
Results and Impact | Oral presentation given by the PI (IHFS) during the Minisymposium on Poroelasticity and Rock Physics 2024 |
Year(s) Of Engagement Activity | 2024 |
URL | https://rockphysics.org/en/minisymposium |
Description | Workshop organization - NOC, Southampton, UK (12th May 2023) |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | Workshop organized in the NOC to discuss the present and the future of the underground gas storage, from a multiscale and multi-disciplinary viewpoint, internationally. We shared opinions from industry and academia to explore crucial areas of investigation and potential collaborations to efficiently contribute to achieve the energy transition objectives. In the workshop we counted with the presence of stakeholders (oil and gas majors: ENI, BP), professors from University of Southampton, University of Sao Paulo, and the NOC. |
Year(s) Of Engagement Activity | 2023 |