Simulating permeability reduction by clay mineral nanopores in a tight sandstone by combining computer X-ray microtomography and focussed ion beam scanning electron microscopy imaging

Jacob, Arne; Peltz, Markus; Hale, Sina; Enzmann, Frieder; Moravcova, Olga; Warr, Laurence N.; Grathoff, Georg; Blum, Philipp; Kersten, Michael

doi:10.5194/se-12-1-2021

Cited by 24 publications

(12 citation statements)

References 63 publications

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“…Blue and red circles represent data from this study, made parallel and perpendicular to the plane of shear, respectively. Grey circles show porosity data for Unzen from Mueller et al (2005) and Kendrick et al (2021), and open circles show permeability measurement on USDP drill cores from Watanabe et al (2008). Other symbols show data for effusive products at similar dome eruptions.…”

Section: Discussionmentioning

confidence: 99%

“…The rocks sampled across the shear zone and in the fault gouge at Mount Unzen vary in porosity between 8 % and 27 %; this range is slightly narrower than the porosity range (4-48 %) covered by blocks shed by pyroclastic density currents originating from the domes during the 5-year eruption (see Fig. 8; Kueppers et al, 2005;Coats et al, 2018;Kendrick et al, 2021;Scheu et al, 2007;Mueller et al, 2005). The narrower range exhibited by the spine shear zones may reflect the occurrence of fewer porosity-modifying mechanisms (e.g.…”

Section: Permeability In Volcanic Environmentsmentioning

confidence: 96%

“…3), which are more susceptible to closure by increasing effective pressure than equant pores (e.g., Kendrick et al, 2021). Although this process occurs during confinement in both orientations, it only impacts permeability perpendicular to shear direction, and so contributes to enhanced anisotropy of permeability in banded shear fabrics under confinement (Kendrick et al, 2021).…”

Section: Permeability Across the Marginal Shear Zonementioning

confidence: 99%

“…8; Klug and Cashman, 1996;Mueller et al, 2005;Farquharson et al, 2015) for various types of volcanic rocks (e.g. explosive clasts vs effusive lavas), including the presence of heterogeneous structures (Farquharson et al, 2016c;Kolzenburg et al, 2012;Lamur et al, 2017;Kendrick et al, 2021), and these constraints have been invoked in diverse models to assess how magma permeability may evolve leading to eruption (Burgisser et al, 2019;Edmonds et al, 2003). However, the deformability of magma imposes constant changes to the porous permeable network and to date, only a few studies have measured or assessed the transience of permeability and porosity during magma deformation (Okumura et al, 2010(Okumura et al, , 2012Kendrick et al, 2013;Ashwell et al, 2015;Kennedy et al, 2016), especially in operando (Kushnir et al, 2017;Wadsworth et al, 2017;Wadsworth et al, 2021).…”

Section: Permeability In Volcanic Environmentsmentioning

confidence: 99%

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Transient conduit permeability controlled by a shift between compactant shear and dilatant rupture at Unzen volcano (Japan)

Lavallée

Miwa

Ashworth

et al. 2021

Preprint

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Abstract. The permeability of magma in shallow volcanic conduits controls the fluid flow and pore pressure development that regulates gas emissions and the style of volcanic eruptions. The architecture of the permeable porous structure is subject to changes as magma deforms and outgasses during ascent. Here, we present a high-resolution study of the permeability distribution across two conduit shear zones (marginal and central) developed in the dacitic spine that extruded towards the closing stages of the 1991–1995 eruption at Unzen volcano, Japan. The marginal shear zone is approximately 3.2 m wide and exhibits a 2-m wide, moderate shear zone with porosity and permeability similar to the conduit core, transitioning into a ~1-m wide, highly-sheared region with relatively low porosity and permeability, and an outer 20-cm wide cataclastic fault zone. The low porosity, highly-sheared rock further exhibits an anisotropic permeability network with slightly higher permeability along the shear plane (parallel to the conduit margin) and is locally overprinted by oblique dilational Riedel fractures. The central shear zone is defined by a 3-m long by ~9-cm wide fracture ending bluntly and bordered by a 15–40 cm wide damage zone with an increased permeability of ~3 orders of magnitude; directional permeability and resultant anisotropy could not be measured from this exposure. We interpret the permeability and porosity of the marginal shear zone to reflect the evolution of compactional (i.e., ductile) shear during ascent up to the point of rupture, estimated by Umakoshi et al. (2008), at ~500 m depth. At this point the compactional shear zone would have been locally overprinted by brittle rupture, promoting the development of a shear fault and dilational Riedel fractures during repeating phases of increased magma ascent rate, enhancing anisotropic permeability that channels fluid flow into, and along, the conduit margin. In contrast, we interpret the central shear zone as a shallow, late-stage dilational structure, which partially tore the spine core with slight displacement. We explore constraints from monitored seismicity and stick-slip behaviour to evaluate the rheological controls, which accompanied the upward shift from compactional toward dilational shear as magma approached the surface, and discuss their importance in controlling the permeability development of magma evolving from overall ductile to increasingly brittle behaviour during ascent and eruption.

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Section: Discussionmentioning

confidence: 99%

Section: Permeability In Volcanic Environmentsmentioning

confidence: 96%

Section: Permeability Across the Marginal Shear Zonementioning

confidence: 99%

Section: Permeability In Volcanic Environmentsmentioning

confidence: 99%

See 2 more Smart Citations

Transient conduit permeability controlled by a shift between compactant shear and dilatant rupture at Unzen volcano (Japan)

Lavallée

Miwa

Ashworth

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…Thus, DRP can complement challenging laboratory measurements or provide estimated properties when accurate laboratory measurements are not available. [13][14][15][16][17][18][19] Labeled images from image segmentation are assigned physical properties of the known materials for advanced mathematical simulations of physical characteristics such as flow behavior, electrical and thermal conductivity, and elasticity. [13][14][15][16][17]19] The results of these simulations can then be reviewed in the context of the changing structural framework.…”

Section: Introductionmentioning

confidence: 99%

Multi-physics evaluation of carbonate-rich source rocks from high-resolution images

2021

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In unconventional reservoirs, the pore space is hosted by a heterogeneous matrix with various minerals and organic components. This heterogeneity complicates petrophysical interpretation during hydrocarbon exploration. A digital rock physics study of thermal and electrical conductivity was conducted using high-resolution focused ion beam scanning electron microscopy images of carbonate-rich source rocks. Finite-volume simulation results are discussed in context of the sample heterogeneity and anisotropy and supported by comparisons to empirical equations and effective medium theory. The results show how the presence of organic matter, pyrite, and pore constrictions impacts application of empirical equations and simplified models to unconventional reservoirs. Graphic abstract

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Fluid–Rock Interactions in Geothermal Reservoirs, Germany: Thermal Autoclave Experiments Using Sandstones and Natural Hydrothermal Brines

et al. 2022

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As renewable energy, geothermal can contribute substantially to the energy transition. To generate electricity or to harvest heat, high-saline fluids are tapped by wells of a few kilometres and extracted from hydrothermal reservoirs. After the heat exchanger units have been passed by, these fluids are reinjected into the reservoir. Due to the pressure and temperature differences between the subsurface and the surface, as well as the cooling of the fluids in the power plant, unwanted chemical reactions can occur within the reservoir, in the borehole, and within the power plant itself. This can reduce the permeability of the reservoir as well as the output of the geothermal power plant. This study aims to simulate real subsurface reactions using batch and leaching experiments with sandstone or sandstone powder as solid phase, and deionised water or natural brine as liquid phase. It is demonstrated that fluid composition changes after only a few days. In particular, calcite, aragonite, clay minerals, and zinc phases precipitate from the natural brine. In contrast, in particular minerals containing potassium, arsenic, barium, and silica are dissolved. Due to the experimental set-up, these mineral reactions mainly took place on the surface of the samples, which is why no substantial changes in petrophysical properties could be observed. However, it is assumed that the observed reactions on the reservoir scale have a relevant influence on parameters such as permeability.

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Simulating permeability reduction by clay mineral nanopores in a tight sandstone by combining computer X-ray microtomography and focussed ion beam scanning electron microscopy imaging

Cited by 24 publications

References 63 publications

Transient conduit permeability controlled by a shift between compactant shear and dilatant rupture at Unzen volcano (Japan)

Transient conduit permeability controlled by a shift between compactant shear and dilatant rupture at Unzen volcano (Japan)

Multi-physics evaluation of carbonate-rich source rocks from high-resolution images

Fluid–Rock Interactions in Geothermal Reservoirs, Germany: Thermal Autoclave Experiments Using Sandstones and Natural Hydrothermal Brines

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