Laboratory demonstration of hydraulic fracture height growth across weak discontinuities

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Laboratory demonstration of hydraulic fracture height growth across weak discontinuities. / Xing, Pengju; Yoshioka, Keita; Adachi, Jose et al.
in: Geophysics, Jahrgang 83.2018, Nr. 2, 2018, S. MR93-MR105.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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Xing P, Yoshioka K, Adachi J, El-Fayoumi A, Bunger AP. Laboratory demonstration of hydraulic fracture height growth across weak discontinuities. Geophysics. 2018;83.2018(2):MR93-MR105. doi: 10.1190/GEO2016-0713.1

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Xing, Pengju ; Yoshioka, Keita ; Adachi, Jose et al. / Laboratory demonstration of hydraulic fracture height growth across weak discontinuities. in: Geophysics. 2018 ; Jahrgang 83.2018, Nr. 2. S. MR93-MR105.

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@article{97f476217e1f44d0af17724fb7179f0d,
title = "Laboratory demonstration of hydraulic fracture height growth across weak discontinuities",
abstract = "Decades of research have led to numerous insights in modeling the impact of stresses and rock properties on hydraulic fracture height growth. However, the conditions under which weak horizontal interfaces are expected to impede height growth remain for the most part unknown. We have developed an experimental study of the impact of weak horizontal discontinuities on hydraulic fracture height growth, including the influences of (1) abrupt stress contrasts between layers, (2) material fracture toughness, and (3) contrasts of stiffness between the reservoir and bounding layers. The experiments are carried out with an analog three-layered medium constructed from transparent polyurethane, considering toughnesses resisting vertical fracture growth. There are four observed geometries: containment, height growth, T-shape growth, and the combination of height growth and T-shape. Results are developed in a parametric space embodying the influence of the horizontal stress contrast, vertical stress, and horizontal barrier stress contrast, as well as the fluid pressure. The results indicate that these cases fall within distinct regions when plotted in the parametric space. The locations in the parametric space of these regions are strongly impacted by the vertical fracture toughness: Increasing the value of the vertical interface fracture toughness leads to a suppression of height growth in favor of containment and T-shaped growth. Besides providing detailed experimental data for benchmarking 3D hydraulic fracture simulators, these experiments show that the fracture height is substantially less than would be predicted in the absence of the weak horizontal discontinuities.",
author = "Pengju Xing and Keita Yoshioka and Jose Adachi and Amr El-Fayoumi and Bunger, {Andrew P.}",
year = "2018",
doi = "10.1190/GEO2016-0713.1",
language = "English",
volume = "83.2018",
pages = "MR93--MR105",
journal = "Geophysics",
issn = "0016-8033",
publisher = "Society of Exploration Geophysicists",
number = "2",

}

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TY - JOUR

T1 - Laboratory demonstration of hydraulic fracture height growth across weak discontinuities

AU - Xing, Pengju

AU - Yoshioka, Keita

AU - Adachi, Jose

AU - El-Fayoumi, Amr

AU - Bunger, Andrew P.

PY - 2018

Y1 - 2018

N2 - Decades of research have led to numerous insights in modeling the impact of stresses and rock properties on hydraulic fracture height growth. However, the conditions under which weak horizontal interfaces are expected to impede height growth remain for the most part unknown. We have developed an experimental study of the impact of weak horizontal discontinuities on hydraulic fracture height growth, including the influences of (1) abrupt stress contrasts between layers, (2) material fracture toughness, and (3) contrasts of stiffness between the reservoir and bounding layers. The experiments are carried out with an analog three-layered medium constructed from transparent polyurethane, considering toughnesses resisting vertical fracture growth. There are four observed geometries: containment, height growth, T-shape growth, and the combination of height growth and T-shape. Results are developed in a parametric space embodying the influence of the horizontal stress contrast, vertical stress, and horizontal barrier stress contrast, as well as the fluid pressure. The results indicate that these cases fall within distinct regions when plotted in the parametric space. The locations in the parametric space of these regions are strongly impacted by the vertical fracture toughness: Increasing the value of the vertical interface fracture toughness leads to a suppression of height growth in favor of containment and T-shaped growth. Besides providing detailed experimental data for benchmarking 3D hydraulic fracture simulators, these experiments show that the fracture height is substantially less than would be predicted in the absence of the weak horizontal discontinuities.

AB - Decades of research have led to numerous insights in modeling the impact of stresses and rock properties on hydraulic fracture height growth. However, the conditions under which weak horizontal interfaces are expected to impede height growth remain for the most part unknown. We have developed an experimental study of the impact of weak horizontal discontinuities on hydraulic fracture height growth, including the influences of (1) abrupt stress contrasts between layers, (2) material fracture toughness, and (3) contrasts of stiffness between the reservoir and bounding layers. The experiments are carried out with an analog three-layered medium constructed from transparent polyurethane, considering toughnesses resisting vertical fracture growth. There are four observed geometries: containment, height growth, T-shape growth, and the combination of height growth and T-shape. Results are developed in a parametric space embodying the influence of the horizontal stress contrast, vertical stress, and horizontal barrier stress contrast, as well as the fluid pressure. The results indicate that these cases fall within distinct regions when plotted in the parametric space. The locations in the parametric space of these regions are strongly impacted by the vertical fracture toughness: Increasing the value of the vertical interface fracture toughness leads to a suppression of height growth in favor of containment and T-shaped growth. Besides providing detailed experimental data for benchmarking 3D hydraulic fracture simulators, these experiments show that the fracture height is substantially less than would be predicted in the absence of the weak horizontal discontinuities.

U2 - 10.1190/GEO2016-0713.1

DO - 10.1190/GEO2016-0713.1

M3 - Article

VL - 83.2018

SP - MR93-MR105

JO - Geophysics

JF - Geophysics

SN - 0016-8033

IS - 2

ER -