Using in situ vertical displacements to characterize changes in moisture load

Murdoch, Lawrence C.; Freeman, C. Edward; Germanovich, L. N.; Thrash, C. J.; DeWolf, Scott

doi:10.1002/2015wr017335

Cited by 10 publications

(7 citation statements)

References 53 publications

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“…It is well known that fluid injection can lead to an increase in pore pressure in a reservoir, a reduction in the effective stress, and a dilation deformation of reservoir rocks. Owing to this fluid-to-solid coupling (Wang, 2017), measuring rock deformation could provide information on the pore pressure and fluid migration (Barbour & Wyatt, 2014;Murdoch et al, 2015). The magnitude of a hydromechanical deformation is dependent on the fluid pressure change and rock stiffness.…”

Section: Introductionmentioning

confidence: 99%

Deformation‐Based Monitoring of Water Migration in Rocks Using Distributed Fiber Optic Strain Sensing: A Laboratory Study

Zhang

Xue

2019

Water Resources Research

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Rock deformation induced by pore‐fluid pressure carries useful information about fluid flow owing to hydromechanical coupling. Thus, obtaining spatiotemporal changes in rock deformation could provide improved understanding of the fluid and pressure migration in aquifers or the role of fluid in the evolution of rainfall‐induced landslide. Here we deployed high‐resolution Rayleigh‐scattering‐type distributed fiber optic strain sensing (DFOSS) to measure rock deformation while injecting water into low‐permeability dry sandstone. X‐ray computed tomography imaging was simultaneously used to visualize the water migration. DFOSS measurements showed the rock developed a dilation deformation that grew during water saturating process. The movement of water wetting front can be revealed by the changes in the measured distributed strain. Strain changes were shaped by poroelastic changes due to the fluid pressure buildup and swelling by the water–clay reaction (i.e., adsorption). The latter mechanism caused increase in the strain when water first entered the dry pore spaces and the change in pore pressure was slight. The mechanism continued contributed to the overall deformation to peak magnitude of ~600 μϵ together with poroelastic mechanism. However, after the rock was fully saturated, further deformation during the flow test can be explained by the poroelastic mechanism alone. Our study suggests that the two factors can be employed as signatures for effectively monitoring fluid behavior in natural sediments using DFOSS. Moreover, we obtained the spatial hydromechanical properties, permeability and stiffness, from the distributed strain measurement and pressure responses. Using DFOSS in the field may substantially improve our ability to monitor and model fluid activity related to rock deformations in reservoirs and rainfall‐induced landslides that would help in warning people of risks and preventing disasters.

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Section: Introductionmentioning

confidence: 99%

Deformation‐Based Monitoring of Water Migration in Rocks Using Distributed Fiber Optic Strain Sensing: A Laboratory Study

Zhang

Xue

2019

Water Resources Research

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“…Although the main purpose of DSS is the monitoring of geomechanical deformations or earth subsidence (for safety considerations) (Kogure and Okuda, 2018;Krietsch et al, 2018;Murdoch et al, 2020;Zhang et al, 2018), DSS could also be used to understand reservoir formation and reservoir Published by Copernicus Publications on behalf of the European Geosciences Union. flow owing to hydromechanical coupling.…”

Section: Introductionmentioning

confidence: 99%

“…Deformation-based reservoir monitoring methods have been recently applied to obtain the lateral permeability distribution (at coarse scales) of underground reservoirs with surface deformation monitored by InSAR technique (Bohloli et al, 2018;Vasco et al, 2008Vasco et al, , 2010 and estimate the vertical compressibility with vertical deformation measured by well-based techniques (e.g., radioactive maker technique and extensometer stations) (Ferronato et al, 2003;Hisz et al, 2013;Murdoch et al, 2015). However, such vertical deformation monitoring tools are usually only available at limited points and over limited time intervals.…”

Section: Introductionmentioning

confidence: 99%

In situ hydromechanical responses during well drilling recorded by fiber-optic distributed strain sensing

et al. 2020

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Abstract. Drilling fluid infiltration during well drilling may induce pore pressure and strain perturbations in neighbored reservoir formations. In this study, we report that such small strain changes (∼20 µε) have been in situ monitored using fiber-optic distributed strain sensing (DSS) in two observation wells with different distances (approximately 3 and 9 m) from the new drilled wellbore in a shallow water aquifer. The results show the layered pattern of the drilling-induced hydromechanical deformation. The pattern could be indicative of (1) fluid pressure diffusion through each zone with distinct permeabilities or (2) the heterogeneous formation damage caused by the mud filter cakes during the drilling. A coupled hydromechanical model is used to interpret the two possibilities. The DSS method could be deployed in similar applications such as geophysical well testing with fluid injection (or extraction) and in studying reservoir fluid flow behavior with hydromechanical responses. The DSS method would be useful for understanding reservoir pressure communication, determining the zones for fluid productions or injection (e.g., for CO2 storage), and optimizing reservoir management and utilization.

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“…Relative deformation instruments like tiltmeters or extensometers have emerged as interesting tools for groundwater hydrology (Barbour & Wyatt, 2014;Chen et al, 2010;Fabian & K€ umpel, 2003;Longuevergne et al, 2009;Murdoch et al, 2015;Vasco et al, 2001). This is because they are able to record accurately and precisely small deformations at high sampling rates compared to spaceborne methods, up to 1 Hz.…”

Section: Introductionmentioning

confidence: 99%

Understanding the Hydromechanical Behavior of a Fault Zone From Transient Surface Tilt and Fluid Pressure Observations at Hourly Time Scales

Schuite

Longuevergne

Bour

et al. 2017

Water Resources Research

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Flow through reservoirs such as fractured media is powered by head gradients which also generate measurable poroelastic deformation of the rock body. The combined analysis of surface deformation and subsurface pressure provides valuable insights of a reservoir's structure and hydromechanical properties, which are of interest for deep‐seated CO2 or nuclear waste storage for instance. Among all surveying tools, surface tiltmeters offer the possibility to grasp hydraulically induced deformations over a broad range of time scales with a remarkable precision. Here we investigate the information content of transient surface tilt generated by the pressurization a kilometer scale subvertical fault zone. Our approach involves the combination of field data and results of a fully coupled poromechanical model. The signature of pressure changes in the fault zone due to pumping cycles is clearly recognizable in field tilt data and we aim to explain the peculiar features that appear in (1) tilt time series alone from a set of four instruments and 2) the ratio of tilt over pressure. We evidence that the shape of tilt measurements on both sides of a fault zone is sensitive to its diffusivity and its elastic modulus. The ratio of tilt over pressure predominantly encompasses information about the system's dynamic behavior and extent of the fault zone and allows separating contributions of flow in the different compartments. Hence, tiltmeters are well suited to characterize hydromechanical processes associated with fault zone hydrogeology at short time scales, where spaceborne surveying methods fail to recognize any deformation signal.

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Using in situ vertical displacements to characterize changes in moisture load

Cited by 10 publications

References 53 publications

Deformation‐Based Monitoring of Water Migration in Rocks Using Distributed Fiber Optic Strain Sensing: A Laboratory Study

Deformation‐Based Monitoring of Water Migration in Rocks Using Distributed Fiber Optic Strain Sensing: A Laboratory Study

In situ hydromechanical responses during well drilling recorded by fiber-optic distributed strain sensing

Understanding the Hydromechanical Behavior of a Fault Zone From Transient Surface Tilt and Fluid Pressure Observations at Hourly Time Scales

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