Capillary Trapping of CO<sub>2</sub> in Sandstone Using Low Field NMR Relaxometry

Connolly, Paul R. J.; Vogt, Sarah J.; Mahmoud, Mohamed; Ng, Christopher N. Y.; May, Eric F.; Johns, Michael L.

doi:10.1029/2019wr026294

Cited by 14 publications

(3 citation statements)

References 54 publications

(77 reference statements)

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“…This intriguing correlation will be explored further via a wider suite of fluids, process conditions, and porous media types. Future work will also focus on further assessment of the correlation of the values of T 2 to an approximate quantitative pore size – specifically we will further define the relaxation regime occupied by these high pressure liquid and supercritical fluids; ,, preliminary analysis suggests they are consistently just within the short-time regime where eqs and are broadly valid.…”

Section: Results and Discussionmentioning

confidence: 99%

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT₂Relaxation Time Measurements

Yang

Connolly

et al. 2020

Ind. Eng. Chem. Res.

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NMR T 2 relaxation times for fluids in a porous medium are, in principle, proportional to the relevant occupied pore size. Here, we exploit this relationship to monitor the pore size distribution occupied by methane (CH 4 ) at 100 bar and room temperature in both sandstone and carbonate rock cores, while it is displaced by a range of miscible fluids: carbon dioxide (CO 2 ), nitrogen (N 2 ), nitrous dioxide (N 2 O), and helium (He). The process is then reversed, with methane being used to displace these injected fluids. Time-resolved T 2 distributions are thus able to probe the preference of the methane for smaller or larger pores during these core-flooding processes. In the cases of CO 2 and N 2 O, methane was found to preferentially occupy larger pores during both injection and displacement for both rock types. In the case of N 2 , no significant preferential pore size occupation was evident, whereas in the case of He, methane preferentially occupied smaller pores. For the fluids used in this work, preferential occupation of comparatively smaller pores during these displacement experiments correlated with a comparatively greater surface adsorption capacity.

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Section: Results and Discussionmentioning

confidence: 99%

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT₂Relaxation Time Measurements

Yang

Connolly

et al. 2020

Ind. Eng. Chem. Res.

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“…The lack of superconducting components, for instance, mitigates the need for cryogenic cooling, and so removes the economic cost and maintenance complexity associated with the constant resupply of cryogenic liquids. The associated reduction in size also significantly increases equipment portability (Johns et al, 2015), which when combined with the reduction in safety considerations which accompany both the reduced magnetic field strengths inherent to permanent magnets and the lack of cryogenic liquids employed, means that benchtop NMR systems may be more readily integrated into simple workbench environments (Sans et al, 2015;Wagner et al, 2016), and/or combined with external equipment (Connolly et al, 2019;Leutzsch et al, 2018;Robinson et al, 2020;Yang et al, 2022). Benchtop spectrometers are also largely maintenance free and can be operated under near push-button conditions, enhancing their suitability for environments without significant NMR expertise, and for high throughput screening applications (Blümich, 2016).…”

Section: Low Field Nmr For Meg Composition Monitoringmentioning

confidence: 99%

Quantitative measurement of Mono-Ethylene Glycol (MEG) content using low-field Nuclear Magnetic Resonance (NMR)

Shilliday

Barrow

Langford

et al. 2022

Journal of Natural Gas Science and Engineering

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“…For instance, the laboratory NMR system is uniquely sensitive to capillary trapping parameters in rock cores, i.e. pore size, relative permeability, wettability and fluid-rock interactions [20]. The obtained knowledge from these laboratory tests is critical to the understanding of many geoscience scenarios, including hydrocarbon recovery, underground energy storage, such as hydrogen, and carbon sequestration.…”

Section: Introductionmentioning

confidence: 99%

Integration of an optical FBG sensor into a nuclear magnetic resonance core flooding system

Esteban

Giwelli

Kovalyshen

2022

Meas. Sci. Technol.

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A new platen was designed and developed for Nuclear Magnetic Resonance (NMR) core flooding cell to integrate Fibre Bragg Grating (FBG) strain sensors. The platen is made from carbon fibre material with a special channel to insert FBG inside the cell, and it is compatible with NMR overburden system (i.e., no metal, and it’s resistant to pressure, temperature and reactive chemicals) to allow advanced chemical experiments and the like. This development has allowed us to acquire both fluid dynamics behaviour, from NMR, and deformation/elastic properties, from FBG sensors, during NMR core flooding experiments for advanced hydro-mechanical-chemical coupling characterisation. Generally, pore fluid redistribution occurs while changing the surrounding stress and/or temperature conditions of the tested material, will generate elastic and geomechanical responses. The impact of rock-fluid interactions during NMR core flooding has not been evaluated until now, mainly due to technical limitations. Fortunately, FBG sensing technique is a localised/discreet micro-strain gauges (a 8 mm long and 125 micro thick), and it is applicable to monitor pseudo-tomography during core flooding experiments. We recently managed to attached 8 FBG sensors on a carbonate rock plug to monitor strain alteration during brine imbibition under 800 psi confining pressure. Results validates the capacity of FBG sensors to track mechanical strength alteration due to pore pressure changes and also detect waterfront velocity during injection. The integrated FBG sensors into NMR core flooding has added a new capability to NMR overburden system to simultaneously monitor material deformation with FBG sensors during pressure/temperature alterations as a first basic application.

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Capillary Trapping of CO₂ in Sandstone Using Low Field NMR Relaxometry

Cited by 14 publications

References 54 publications

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT₂Relaxation Time Measurements

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT₂Relaxation Time Measurements

Quantitative measurement of Mono-Ethylene Glycol (MEG) content using low-field Nuclear Magnetic Resonance (NMR)

Integration of an optical FBG sensor into a nuclear magnetic resonance core flooding system

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Capillary Trapping of CO2 in Sandstone Using Low Field NMR Relaxometry

Cited by 14 publications

References 54 publications

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT2Relaxation Time Measurements

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT2Relaxation Time Measurements

Quantitative measurement of Mono-Ethylene Glycol (MEG) content using low-field Nuclear Magnetic Resonance (NMR)

Integration of an optical FBG sensor into a nuclear magnetic resonance core flooding system

Contact Info

Product

Resources

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Capillary Trapping of CO₂ in Sandstone Using Low Field NMR Relaxometry

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT₂Relaxation Time Measurements

Miscible Fluid Displacement in Rock Cores Evaluated with NMRT₂Relaxation Time Measurements