Inelastic compaction and permeability evolution in volcanic rock

Farquharson, Jamie; Baud, Patrick; Heap, Michael

doi:10.5194/se-8-561-2017

Cited by 41 publications

(15 citation statements)

References 101 publications

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“…The procedure for triaxial experiments in Strasbourg was described in detail by Baud et al (2015) and Farquharson, Baud, and Heap (2017). Jacketed samples were deformed at a nominal strain rate of 10 À5 /s at confining pressures ranging from 3 to 120 MPa.…”

Section: Experimental Methodology For Deformation Experimentsmentioning

confidence: 99%

Inelastic Compaction in High‐Porosity Limestone Monitored Using Acoustic Emissions

et al. 2017

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We performed a systematic investigation of mechanical compaction and strain localization in Saint‐Maximin limestone, a quartz‐rich, high‐porosity (37%) limestone from France. Our new data show that the presence of a significant proportion of secondary mineral (i.e., quartz) did not impact the mechanical strength of the limestone in both the brittle faulting and cataclastic flow regimes, but that the presence of water exerted a significant weakening effect. In contrast to previously published studies on deformation in limestones, inelastic compaction in Saint‐Maximin limestone was accompanied by abundant acoustic emission (AE) activity. The location of AE hypocenters during triaxial experiments revealed the presence of compaction localization. Two failure modes were identified in agreement with microstructural analysis and X‐ray computed tomography imaging: compactive shear bands developed at low confinement and complex diffuse compaction bands formed at higher confinement. Microstructural observations on deformed samples suggest that the recorded AE activity associated with inelastic compaction, unusual for a porous limestone, could have been due to microcracking at the quartz grain interfaces. Similar to published data on high‐porosity macroporous limestones, the crushing of calcite grains was the dominant micromechanism of inelastic compaction in Saint‐Maximin limestone. New P wave velocity data show that the effect of microcracking was dominant near the yield point and resulted in a decrease in P wave velocity, while porosity reduction resulted in a significant increase in P wave velocity beyond a few percent of plastic volumetric strain. These new data highlight the complex interplay between mineralogy, rock microstructure, and strain localization in porous rocks.

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Section: Experimental Methodology For Deformation Experimentsmentioning

confidence: 99%

Inelastic Compaction in High‐Porosity Limestone Monitored Using Acoustic Emissions

et al. 2017

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“…Forty-two samples (Table 3) were deformed uniaxially at a constant strain rate of 1.0 × 10 −5 s −1 until macroscopic failure in a servo-controlled deformation apparatus (described by Heap et al (2014) and Farquharson et al (2017)). The piston displacement was controlled and recorded using a linear variable differential transducer (LVDT) and the force on the sample was monitored using a load cell.…”

Section: Uniaxial Compressive Strengthmentioning

confidence: 99%

Characterizing the physical properties of rocks from the Paleozoic to Permo-Triassic transition in the Upper Rhine Graben

et al. 2018

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Background Geothermal energy has emerged as an attractive alternative to fossil fuel resources in part because it represents a carbon-free energy supply that can be exploited regardless of the time of day or year. Of particular interest is the increasing economic viability and technological feasibility of geothermal exploitation in non-volcanic environments. For example, the last 30 years has seen the development of economically viable deep geothermal resources in continental Europe, where electricity and heat are being generated by exploiting the high geothermal gradients extant in intracratonic basins, crystalline

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“…This hierarchical subdivision is based on international conventions (e.g. Bates and Jackson, 1987;Gillespie and Styles, 1999;Robertson, 1999;Hallsworth and Knox, 1999;Le Bas and Streckeisen, 1991;Schmid, 1981;Fisher and Smith, 1991). Furthermore, the classification corresponds to the subdivision provided by existing property data compilations such as Hantschel and Kauerauf (2009), Schön (2011), and Clauser and Huenges (1995a, b).…”

Section: Petrography or Rock Typementioning

confidence: 99%

The PetroPhysical Property Database (P<sup>3</sup>) – a global compilation of lab-measured rock properties

Bär

Reinsch

Sippel

2020

Earth Syst. Sci. Data

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Abstract. Petrophysical properties are key to populating local and/or regional numerical models and to interpreting results from geophysical investigation methods. Searching for rock property values measured on samples from a specific rock unit at a specific location might become a very time-consuming challenge given that such data are spread across diverse compilations and that the number of publications on new measurements is continuously growing and data are of heterogeneous quality. Profiting from existing laboratory data to populate numerical models or interpret geophysical surveys at specific locations or for individual reservoir units is often hampered if information on the sample location, petrography, stratigraphy, measuring method and conditions is sparse or not documented. Within the framework of the EC-funded project IMAGE (Integrated Methods for Advanced Geothermal Exploration, EU grant agreement no. 608553), an open-access database of lab-measured petrophysical properties has been developed (Bär et al., 2017, 2019b: P3 – database, https://doi.org/10.5880/GFZ.4.8.2019.P3. The goal of this hierarchical database is to provide easily accessible information on physical rock properties relevant for geothermal exploration and reservoir characterisation in a single compilation. Collected data include classical petrophysical, thermophysical, and mechanical properties as well as electrical conductivity and magnetic susceptibility. Each measured value is complemented by relevant meta-information such as the corresponding sample location, petrographic description, chronostratigraphic age, if available, and original citation. The original stratigraphic and petrographic descriptions are transferred to standardised catalogues following a hierarchical structure ensuring inter-comparability for statistical analysis (Bär and Mielke, 2019: P3 – petrography, https://doi.org/10.5880/GFZ.4.8.2019.P3.p; Bär et al., 2018, 2019a: P3 – stratigraphy, https://doi.org/10.5880/GFZ.4.8.2019.P3.s). In addition, information on the experimental setup (methods) and the measurement conditions are listed for quality control. Thus, rock properties can directly be related to in situ conditions to derive specific parameters relevant for simulating subsurface processes or interpreting geophysical data. We describe the structure, content and status quo of the database and discuss its limitations and advantages for the end user.

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Inelastic compaction and permeability evolution in volcanic rock

Cited by 41 publications

References 101 publications

Inelastic Compaction in High‐Porosity Limestone Monitored Using Acoustic Emissions

Inelastic Compaction in High‐Porosity Limestone Monitored Using Acoustic Emissions

Characterizing the physical properties of rocks from the Paleozoic to Permo-Triassic transition in the Upper Rhine Graben

The PetroPhysical Property Database (P<sup>3</sup>) – a global compilation of lab-measured rock properties

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Inelastic compaction and permeability evolution in volcanic rock

Cited by 41 publications

References 101 publications

Inelastic Compaction in High‐Porosity Limestone Monitored Using Acoustic Emissions

Inelastic Compaction in High‐Porosity Limestone Monitored Using Acoustic Emissions

Characterizing the physical properties of rocks from the Paleozoic to Permo-Triassic transition in the Upper Rhine Graben

The PetroPhysical Property Database (P&lt;sup&gt;3&lt;/sup&gt;) – a global compilation of lab-measured rock properties

Contact Info

Product

Resources

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The PetroPhysical Property Database (P<sup>3</sup>) – a global compilation of lab-measured rock properties