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Rock Mechanics and Rock Engineering

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28.05.2021 | Original Paper

Experimental and Numerical Characterization of Lower Huron Shale as a Heterogeneous Material

verfasst von: Ming Fan, Yanhui Han, Xinyu Tan, Liang Fan, Ellen S. Gilliland, Nino Ripepi, Cheng Chen

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 8/2021

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Abstract

Understanding mechanical properties of organic rich shale is crucial for successful exploration and long-term production of hydrocarbons from unconventional reservoirs. Due to the organic matter and clay minerals interlaced with other silicate minerals, shale can be studied as a heterogeneous material. In this work, the average mineral compositions and elastic mechanical properties were first characterized by scanning electron microscope, energy-dispersive X-ray spectrometer, and atomic force microscopy. Uniaxial compression and triaxial compression tests were then conducted on core-scale Lower Huron Shale samples. Numerical models were constructed to extract mechanical properties from both uniaxial compression and triaxial compression experiments. Next, homogeneous, mineral-based, and Weibull distribution-based numerical models were developed to investigate the influence of the mineral heterogeneity and shale hydration effect on the strength and deformation behavior of shale rocks. The homogeneous models have higher compressive and tensile strengths as well as mechanical properties than heterogeneous models. Compared to homogeneous models, when the shale rock is simulated with heterogeneous models, a transformation from brittle to ductile in stress–strain responses and that from simple modes to complex modes in failure mechanisms are observed. It is also demonstrated that the mineral property distribution and shale hydration effect have a larger influence on the triaxial compression strength. Furthermore, simulation studies suggest that numerical models accounting for the heterogeneity of shale can improve the accuracy of the mechanical property characterization. The outcome of this research will benefit the understanding of the Lower Huron Shale mechanical properties, which has significant implications to the successful development of shale reservoirs.

Vorheriger Artikel Experimental and Theoretical Study on Frost Deformation and Damage of Red Sandstones with Different Water Contents

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Abousleiman YN, Hull KL, Han Y, Al-Muntasheri G, Hosemann P, Parker S, Howard CB (2016) The granular and polymer composite nature of kerogen-rich shale. Acta Geotech 11(3):573–594CrossRef

Bennett KC, Berla LA, Nix WD, Borja RI (2015) Instrumented nanoindentation and 3D mechanistic modeling of a shale at multiple scales. Acta Geotech 10(1):1–14CrossRef

Chen S, Yue ZQ, Tham LG (2004) Digital image-based numerical modeling method for prediction of inhomogeneous rock failure. Int J Rock Mech Min Sci 41(6):939–957CrossRef

De Borst RENÉ (1991) Simulation of strain localization: a reappraisal of the Cosserat continuum. Eng Comput 8(4):317–332CrossRef

Ding W, Li C, Li C, Xu C, Jiu K, Zeng W, Wu L (2012) Fracture development in shale and its relationship to gas accumulation. Geosci Front 3(1):97–105CrossRef

Eliyahu M, Emmanuel S, Day-Stirrat RJ, Macaulay CI (2015) Mechanical properties of organic matter in shales mapped at the nanometer scale. Mar Pet Geol 59:294–304CrossRef

Fan M, Chen C (2020) Numerical simulation of the migration and deposition of fine particles in a proppant-supported fracture. J Pet Sci Eng 194:107484 CrossRef

Fan M, McClure J, Han Y, Li Z, Chen C (2018) Interaction between proppant compaction and single-/multiphase flows in a hydraulic fracture. SPE J 23(04):1290–1303CrossRef

Fan M, McClure J, Han Y, Ripepi N, Westman E, Gu M, Chen C (2019) Using an experiment/simulation-integrated approach to investigate fracture-conductivity evolution and non-Darcy flow in a proppant-supported hydraulic fracture. SPE J 24(04):1912–1928CrossRef

Fan M, Han Y, Gu M, McClure J, Ripepi N, Westman E, Chen C (2020) Investigation of the conductivity of a proppant mixture using an experiment/simulation-integrated approach. J Nat Gas Sci Eng 78:103234CrossRef

Fan M, Li Z, Han Y, Teng Y, Chen C (2021) Experimental and numerical investigations of the role of proppant embedment on fracture conductivity in narrow fractures. SPE J 26(01):324–341CrossRef

Grujic OS, Mohaghegh SD, Bromhal GS (2010) Fast track reservoir modeling of shale formations in the Appalachian Basin. Application to Lower Huron Shale in Eastern Kentucky. Soc Pet Eng. https://doi.org/10.2118/139101-MSCrossRef

Han Y, Al-Muntasheri G, Katherine LH, Abousleiman YN (2016) Tensile mechanical behavior of kerogen and its potential implication to fracture opening in kerogen-rich shales (KRS). In: 50th US rock mechanics/geomechanics symposium. American Rock Mechanics Association

Han Y, Abousleiman YN, Hull KL, Al-Muntasheri GA (2017) Numerical modeling of elastic spherical contact for Mohr–Coulomb type failures in micro-geomaterials. Exp Mech 57(7):1091–1105CrossRef

Han Y, Detournay C, Cundall P, Abousleiman Y (2018) Investigation of Kerogen's effects on hydraulic fracturing using a micromechanical HF simulator. In: 52nd US rock mechanics/geomechanics symposium. American Rock Mechanics Association

Herrmann J, Rybacki E, Sone H, Dresen G (2018) Deformation experiments on Bowland and Posidonia Shale—part I: strength and young’s modulus at ambient and in situ p c–T conditions. Rock Mech Rock Eng 51(12):3645–3666CrossRef

Hua Y (2014) PeakForce-QNM advanced applications training 2014. Bruker

Islam MA, Skalle P (2013) An experimental investigation of shale mechanical properties through drained and undrained test mechanisms. Rock Mech Rock Eng 46(6):1391–1413CrossRef

Itasca (2011) Fast Lagrangian analysis of Continua v7.0. Minneapolis, Minnesota

Jaeger JC, Cook NG, Zimmerman R (2009) Fundamentals of rock mechanics. Wiley

Jarvie DM, Hill RJ, Ruble TE, Pollastro RM (2007) Unconventional shale-gas systems: the Mississippian Barnett Shale of north-central Texas as one model for thermogenic shale-gas assessment. AAPG Bull 91(4):475–499CrossRef

Keller LM, Schwiedrzik JJ, Gasser P, Michler J (2017) Understanding anisotropic mechanical properties of shales at different length scales: in situ micropillar compression combined with finite element calculations. J Geophys Res Solid Earth 122(8):5945–5955CrossRef

Kohli AH, Zoback MD (2013) Frictional properties of shale reservoir rocks. J Geophys Res Solid Earth 118(9):5109–5125CrossRef

Kumar V, Sondergeld C, Rai CS (2015) Effect of mineralogy and organic matter on mechanical properties of shale. Interpretation 3(3):SV9–SV15CrossRef

Li C, Ostadhassan M, Guo S, Gentzis T, Kong L (2018) Application of PeakForce tapping mode of atomic force microscope to characterize nanomechanical properties of organic matter of the Bakken Shale. Fuel 233:894–910CrossRef

Lin C, Kang YL, You LJ, Yan XP, Chen Q (2019). Effect of fluid exposure on mechanical properties of organic-rich shale and field applications. In: Proceedings of the international field exploration and development conference 2017. Springer, Singapore, pp 1746–1760

Liu HY, Roquete M, Kou SQ, Lindqvist PA (2004) Characterization of rock heterogeneity and numerical verification. Eng Geol 72(1–2):89–119CrossRef

Liu X, Zeng W, Liang L, Xiong J (2016) Experimental study on hydration damage mechanism of shale from the Longmaxi Formation in southern Sichuan Basin, China. Petroleum 2(1):54–60CrossRef

Lu Y, Li Y, Wu Y, Luo S, Jin Y, Zhang G (2020) Characterization of shale softening by large volume-based nanoindentation. Rock Mech Rock Eng 53:1393–1409CrossRef

Mavko G, Mukerji T, Dvorkin J (2020) The rock physics handbook. Cambridge University PressCrossRef

Papanastasiou PC, Vardoulakis IG (1989) Bifurcation analysis of deep boreholes: II. Scale effect. Int J Numer Anal Methods Geomech 13(2):183–198CrossRef

Papanastasiou PC, Vardoulakis IG (1992) Numerical treatment of progressive localization in relation to borehole stability. Int J Numer Anal Methods Geomech 16(6):389–424CrossRef

Papanastasiou P, Zervos A (2004) Wellbore stability analysis: from linear elasticity to postbifurcation modeling. Int J Geomech 4(1):2–12CrossRef

Pittenger B, Erina N, Su C (2010) Quantitative mechanical property mapping at the nanoscale with PeakForce QNM. Application Note Veeco Instruments Inc, pp 1–12

Rassouli FS, Ross CM, Zoback MD, Andrew M (2017) Shale rock characterization using multi-scale imaging. In: 51st US rock mechanics/geomechanics symposium. American Rock Mechanics Association

Rickman R, Mullen MJ, Petre JE, Grieser WV, Kundert D (2008) A practical use of shale petrophysics for stimulation design optimization: all shale plays are not clones of the Barnett Shale. In SPE annual technical conference and exhibition. Society of Petroleum Engineers

Rybacki E, Reinicke A, Meier T, Makasi M, Dresen G (2015) What controls the mechanical properties of shale rocks?—Part I: strength and Young’s modulus. J Petrol Sci Eng 135:702–722CrossRef

Sone H (2012) Mechanical properties of shale gas reservoir rocks and its relation to the in-situ stress variation observed in shale gas reservoirs (Doctoral dissertation, Stanford University)

Sone H, Zoback MD (2013) Mechanical properties of shale-gas reservoir rocks—part 1: static and dynamic elastic properties and anisotropy. Geophysics 78(5):D381–D392CrossRef

Spikes KT, Dvorkin JP (2004) Reservoir and elastic property prediction away from well control. In: Offshore technology conference. Offshore technology conference

Tan X, Konietzky H, Chen W (2016) Numerical simulation of heterogeneous rock using discrete element model based on digital image processing. Rock Mech Rock Eng 49(12):4957–4964CrossRef

Tang CA, Liu H, Lee PKK, Tsui Y, Tham L (2000) Numerical studies of the influence of microstructure on rock failure in uniaxial compression—part I: effect of heterogeneity. Int J Rock Mech Min Sci 37(4):555–569CrossRef

Tham LG, Cheung YK, Tang CA (2001) Numerical simulation of the failure process of rocks. Tamkang J Sci Eng 4(4):239–252

Veytskin YB, Tammina VK, Bobko CP, Hartley PG, Clennell MB, Dewhurst DN, Dagastine RR (2017) Micromechanical characterization of shales through nanoindentation and energy dispersive X-ray spectrometry. Geomech Energy Environ 9:21–35CrossRef

Wang F, Konietzky H, Herbst M (2019) Influence of heterogeneity on thermo-mechanical behaviour of rocks. Comput Geotech 116:103184CrossRef

Wang F, Konietzky H, Fruehwirt T, Li Y, Dai Y (2020) Impact of cooling on fracturing process of granite after high-speed heating. Int J Rock Mech Min Sci 125:104155CrossRef

Wei C (2015) Damage characteristics of brittle rocks inside the pre-failure range: numerical simulation and lab testing. Technischen Universität Bergakademie Freiberg

Weibull W (1951) A statistical distribution function of wide applicability. J Appl Mech 103:293–297CrossRef

Wong TF, Wong RH, Chau KT, Tang CA (2006) Microcrack statistics, Weibull distribution and micromechanical modeling of compressive failure in rock. Mech Mater 38(7):664–681CrossRef

Zhang Y, Niu S, Du Z, Hao J, Yang J (2020) Dynamic fracture evolution of tight sandstone under uniaxial compression in high resolution 3D X-ray microscopy. J Pet Sci Eng 195:107585 CrossRef

Titel: Experimental and Numerical Characterization of Lower Huron Shale as a Heterogeneous Material
verfasst von: Ming Fan
Yanhui Han
Xinyu Tan
Liang Fan
Ellen S. Gilliland
Nino Ripepi
Cheng Chen
Publikationsdatum: 28.05.2021
Verlag: Springer Vienna
Erschienen in: Rock Mechanics and Rock Engineering / Ausgabe 8/2021
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-021-02491-2

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