The Origin of Non-thermal Fluctuations in Multiphase Flow in Porous Media

Rücker, Maja; Georgiadis, Apostolos; Armstrong, Ryan T.; Ott, Holger; Brussee, Niels; Linde, Hilbert van der; Simon, Ludwig; Enzmann, Frieder; Kersten, Michael; Berg, Steffen

doi:10.3389/frwa.2021.671399

Cited by 21 publications

(23 citation statements)

References 80 publications

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“…Recent research has proposed that these pressure fluctuations are capillary effects Rucker et al. (2021). This suggests that the fluctuations present in the pressure data may provide a link between flow processes across scales.…”

Section: Introductionmentioning

confidence: 99%

“…Consequently, there is extensive literature on steady-state relative permeability, but in most cases the raw pressure data is not shown. Recent research has proposed that these pressure fluctuations are capillary effects Rucker et al (2021). This suggests that the fluctuations present in the pressure data may provide a link between flow processes across scales.…”

mentioning

confidence: 99%

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Red Noise in Steady‐State Multiphase Flow in Porous Media

Spurin

Rücker

Moura

et al. 2022

Water Resources Research

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Red Noise in Steady‐State Multiphase Flow in Porous Media

Spurin

Rücker

Moura

et al. 2022

Water Resources Research

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“…In the context of CO 2 sequestration, the entrapment of a non-wetting phase through ganglia formation helps to immobilize CO 2 in the pore space [Iglauer et al, 2011, Zuo et al, 2017, whereas it is detrimental to hydrocarbon production in the context of enhanced oil recovery. Snap-off occurs when a non-wetting fluid displaces a wetting fluid in porethroat constrictions (Figure 5), leading to the breakup of droplets and formation of ganglia [Berg et al, 2013, Andrew et al, 2014a, Rucker et al, 2021, Tanino and Blunt, 2012.…”

Section: Fluid Flow and Multi-phase Flowmentioning

confidence: 99%

Four-dimensional X-ray micro-tomography imaging of dynamic processes in geosciences

Noiriel¹,

Renard²

2022

Comptes Rendus. Géoscience

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The dynamic response of rocks to thermal, hydrodynamical, mechanical, and geochemical solicitations is of fundamental interest in several disciplines of geosciences, including geoengineering, geophysics, rock physics, hydrology, mineralogy, and environmental and soil sciences. From crystal shape to rock microstructure or pore space and fluid distribution, parameters characterizing the rock physico-chemical properties evolve at different time and spatial scales. X-ray micro-tomography (XMT), as a non-invasive and non-destructive imaging technique, offers an unprecedented opportunity to add the fourth dimension, i.e. time, to the three-dimensional spatial visualization of rock and mineral microstructures. The technique is increasingly used to explore dynamic processes in porous and fractured rocks, thanks to synchrotron sources and laboratory XMT scanners, new generations of detectors, and increasing computational power. Image processing allows for tracking the evolution of the fluid-fluid or fluid-mineral interfaces as well as measuring incremental deformations, as rocks deform and react through time under in situ conditions of the sub-surface. Here, we review recent advances in 4D X-ray micro-tomography applied to thermohydro-mechano-chemical (THMC) sub-surface processes where fluids, porosity, minerals, and rock microstructures evolve together.Keywords. X-ray micro-tomography, 4D imaging, Mineral reactivity, Reactive flow, Rock deformation, Multi-phase flow, Thermo-hydro-mechano-chemical processes.Note. Submission by invitation of the editorial board. Catherine Noiriel is the 2020 recipient of the Prix Schlumberger of the Académie des sciences / Soumission sur invitation du comité de rédaction. Catherine Noiriel est la lauréate 2020 du Prix Schlumberger de l'Académie des sciences.

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“…The relative permeability data were measured using the steady-state method, following the Shell internal standard protocols (Kokkedee et al 1996;Rücker et al 2021), combining insitu saturation monitoring with accurate pressure measurements and bump floods at the end of the tests (Berg et al 2021a, b). The imbibition capillary pressure curves were measured on twin samples, using multi-speed centrifuge, on set-ups equipped with automatic data acquisition (Masalmeh et al 2014).…”

Section: Relative Permeability and Capillary Pressure Measurementmentioning

confidence: 99%

Multiscale Digital Rock Analysis for Complex Rocks

et al. 2021

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Many properties of complex porous media such as reservoir rocks are strongly affected by heterogeneity at different scales. Complex depositional and diagenetic processes have a strong control on the pore structures, leading to systems with a wide range of pore sizes covering many orders of magnitude in length scales. This poses a significant challenge for digital rock analysis since a single resolution image and associated simulation model cannot capture all the relevant length scales in sufficient detail due to limitations in computer memory and speed. The scale-transgressive effects of heterogeneity must therefore be accounted for through a multiscale digital rock workflow. We introduce a generalized multiscale imaging and pore-scale modelling workflow to derive transport properties of complex rocks having broad pore size distributions. A dry/wet micro-CT imaging sequence is used to spatially map the porosity and the connectivity of resolved and unresolved porous regions. The unresolved porosity regions are classified into different porosity classes or rock types. The resulting 3D rock-type map and the porosity map are combined and transformed into a multiscale pore network model. Resolved pores are treated in a conventional pore network manner while unresolved network elements are treated as a continuum Darcy-type porous medium. Similar to conventional continuum models, each Darcy pore is populated with single and multiphase flow properties. These properties are derived from high-resolution rock-type models constructed from backscatter SEM images and/or high-resolution micro-CT images of sub-samples. The multiscale digital rock workflow is applied to two heterogeneous rock samples: a mixed wet thinly laminated reservoir sandstone and an oil wet reservoir carbonate. Experimentally measured mercury-air primary drainage and oil-water imbibition capillary pressure curves (after ageing to restore wettability) are used to anchor the multiscale pore network model. Waterflood relative permeability is calculated in a blind test and compared with high-quality experimental data. A very encouraging agreement between computed and measured properties is found.

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The Origin of Non-thermal Fluctuations in Multiphase Flow in Porous Media

Cited by 21 publications

References 80 publications

Red Noise in Steady‐State Multiphase Flow in Porous Media

Red Noise in Steady‐State Multiphase Flow in Porous Media

Four-dimensional X-ray micro-tomography imaging of dynamic processes in geosciences

Multiscale Digital Rock Analysis for Complex Rocks

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