Your search keyword '"Burbey, Thomas J."' showing total 29 results

1. Spatiotemporal subsidence feature decomposition and hotspot identification.

Author

Chu, Hone-Jay, Tatas, Patra, Sumriti Ranjan, and Burbey, Thomas J.

Subjects

LAND subsidence, HILBERT-Huang transform, GROUNDWATER monitoring, ORTHOGONAL functions, HYDROGEOLOGY, GEOLOGIC hot spots

Abstract

Subsidence occurs from excessive groundwater drawdown, but varies in response to underlying hydrogeologic conditions, land use factors, and variations of pumping rates. For subsidence feature decomposition, the empirical orthogonal function (EOF) is used to identify to extract the main components of the land subsidence data, such as continuous trend of subsidence and seasonal subsidence from various regions. Result shows that the major subsidence feature components contain the long-term, periodic (seasonal), and intra-seasonal ones which are related to human activities and hydrogeology from the inland, distal-fan area and coastal area in west-central Taiwan. The subsidence trend and seasonal variation at the observations can be separated from empirical mode decomposition (EMD) for validation. Moreover, subsidence and groundwater monitoring data are used to generate the stress–strain relations at the major EOFs locations. The outcome implies a strongly elastic nature, yet reveals a diverse correlation between stress and strain within the subsidence region. The decomposition and identification of subsidence features offer valuable applications for the effective management of land subsidence and groundwater resources. [ABSTRACT FROM AUTHOR]

Published

2024

2. Estimation of annual groundwater changes from InSAR‐derived land subsidence.

Author

Ali, Muhammad Zeeshan, Chu, Hone‐Jay, Tatas, and Burbey, Thomas J.

Subjects

LAND subsidence, GROUNDWATER, SYNTHETIC aperture radar, ALLUVIAL fans, DEFORMATION of surfaces, AQUIFERS

Abstract

Understanding the extent and quantity of groundwater drawdown is critical for developing a mitigation strategy for water management. This study illustrates that the data‐driven model can be used for the spatial estimation of groundwater drawdown using interferometric synthetic aperture radar (InSAR)‐based deformation data. Here, InSAR derived from Sentinel‐1 imagery is used to estimate surface deformations in the Choshui river alluvial fan, Taiwan, between 2016 and 2018. Spatial regression (SR) is applied to estimate the annual groundwater drawdown with a calculated R‐square of 0.96, which is shown to be superior to a nonspatial model. This study demonstrates the potential of the satellite‐based groundwater drawdown map prediction using InSAR‐derived land deformation. In predication, the SR model can reliably catch the patterns of annual predicted drawdown without requiring detailed groundwater observations. [ABSTRACT FROM AUTHOR]

Published

2022

3. Ongoing research on the pumping-induced land deformation in the Aguascalientes Valley: an analysis of the recent data of vertical deformation, groundwater level variations and local seismicity.

Author

Hernandez-Marin, Martin, Esquivel-Ramirez, Ruben, Zermeño-De-Leon, Mario Eduardo, Guerrero-Martinez, Lilia, Pacheco-Martinez, Jesus, and Burbey, Thomas J.

Subjects

LAND subsidence, DATA analysis, REMOTE-sensing images, VALLEYS, EARTHQUAKES

Abstract

In the Aguascalientes valley, middle Mexico, the demand of groundwater from the local aquifer system was suddenly increased after the late 1970s. Since then, several related problems have been occurring or become critical such as land subsidence, ground fissuring, and low-magnitude earthquakes. The most recent data of vertical deformation from PSInSAR, groundwater levels, and earthquakes, has provided critical information regarding the relationship amongst all these processes. In particular, that related to land subsidence, earth fissuring and seismicity. Regarding this, more satellite imagery and data from GPS stations are being revised as a possibility of a more generalized vertical deformation derived with low-magnitude seismicity. A particular seismic event recorded on 6 April 2019 has revealed critical information on the close association between vertical displacements occurred in active faults and low-magnitude seismic events. [ABSTRACT FROM AUTHOR]

Published

2020

4. Parameter estimation of a multiple aquifer-aquitard system from a single extensometer record: Las Vegas, Nevada, USA.

Author

Burbey, Thomas J.

Subjects

PARAMETER estimation, AQUIFERS, AQUITARDS, HYDRAULIC conductivity, WATER levels, RECORDS

Abstract

The purpose of this investigation is to develop a semi-analytical procedure for quantifying aquifer and aquitard properties from a single extensometer record in lieu of the time-consuming development of more complex numerical models to quantify and constrain these parameter values. Despite a limited 12-year record and the fact that water levels both decline and increase on an annual basis, estimates of both aquifer and aquitard parameters have been reasonably estimated at the Lorenzi extensometer site in Las Vegas Valley, Nevada when compared to the estimates developed numerically. The key factors that allow for accurate estimates of elastic and inelastic skeletal specific storage and hydraulic conductivity of the aquitards and elastic specific storage and hydraulic conductivity of the intervening aquifers is the presence of pumping cycles at multiple frequencies, and measured heads at all the aquifer units covered in the extensometer record and the inherent assumption that the aquitards have identical hydrologic characteristics and are homogeneous and isotropic. This latter assumption is also a usual limitation in numerical modelling of these settings because of the complex temporal head relationships occurring within the aquitards that are rarely, if ever, measured. [ABSTRACT FROM AUTHOR]

Published

2020

5. Mapping and predicting subsidence from spatio-temporal regression models of groundwater-drawdown and subsidence observations.

Author

Ali, Muhammad Zeeshan, Chu, Hone-Jay, and Burbey, Thomas J.

Subjects

AQUIFERS, LAND subsidence, REGRESSION analysis, STANDARD deviations, GROUNDWATER recharge, SPATIO-temporal variation, GROUNDWATER

Abstract

Copyright of Hydrogeology Journal is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

6. Spatiotemporal Analysis of Extracted Groundwater Volumes Estimated from Electricity Consumption.

Author

Chu, Hone‐Jay, Lin, Cheng‐Wei, Burbey, Thomas J., and Ali, Muhammad Zeeshan

Subjects

GROUNDWATER analysis, ELECTRIC power consumption, LAND subsidence, ON-chip charge pumps

Abstract

Land subsidence caused by groundwater overexploitation is a serious global problem. The acquisition of spatiotemporal pumping rates and volumes is a first step for water managers to develop a strategic plan for mitigating land subsidence. This study investigates an empirical formulation to estimate the monthly maximum pumped volume over a 10‐year period based on electric power consumption data. A spatiotemporal variability analysis of monthly pumped volume is developed to provide an improved understanding of seasonal pumping patterns and the role of irrigation type. The analysis of regional pumped volume provides an approximation of the spatiotemporal patterns of the variations in pumped volume. Results show the effects of climate, seasonal changes in pumping from irrigation, and the local differences in pumping caused to crop types. A seasonal pumped volume peak occurs annually, with the highest and least pumped volumes occurring in March (highest peak) and September (lowest peak), respectively. However, the majority of the historical maximum pumped volumes have occurred during the last few years. Extracted volumes continue to increase in some locations. The analysis reveals increasing trends in pumping, thereby possibly providing the locations where increased effective stresses may lead to land subsidence. Article impact statement: The study provides the spatiotemporal patterns in pumped volume estimated from electricity consumption data, especially maximum pumped volumes. [ABSTRACT FROM AUTHOR]

Published

2020

7. Extensometer forensics: what can the data really tell us?

Author

Burbey, Thomas J.

Subjects

EXTENSOMETER, LAND subsidence, HYDRAULIC conductivity, WATER levels, CRUST of the earth, AQUIFERS

Abstract

Copyright of Hydrogeology Journal is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

8. Spatial and temporal variation of natural recharge in the semi-arid valley of Aguascalientes, Mexico.

Author

Hernández-Marín, Martín, Guerrero-Martínez, Lilia, Zermeño-Villalobos, Alfredo, Rodríguez-González, Lorena, Burbey, Thomas J., Pacheco-Martínez, Jesús, Martínez-Martínez, Sergio I., and González-Cervantes, Norma

Subjects

SPATIAL variation, VALLEYS, ZONE of aeration, NUMERICAL analysis, GEOGRAPHIC spatial analysis, AQUIFERS

Abstract

The investigation involves a temporal and spatial analysis to characterize recharge in the Aguascalientes valley in central Mexico. The results are based on a two-part methodological strategy using a geospatial and numerical analysis. Results from the geospatial analysis are based on the analytical hierarchical process (AHP) method, which involves developing a zoning map that qualifies the conditions for groundwater recharge in the valley. In addition, one-dimensional numerical modeling based on the van Genuchten equation was applied for various soil column configurations to estimate the transit time of recharge through the vadose zone. The analysis was performed over a 20-year period from 1995 to 2015. The results of the geospatial analysis indicate that the optimal area for groundwater recharge is the lower zone of the valley, particularly the portion influenced by surface discontinuities. The shortest estimated period of recharge for water to pass through the vadose zone is approximately 4.25 years. [ABSTRACT FROM AUTHOR]

Published

2018

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

Author

Schuite, Jonathan, Longuevergne, Laurent, Bour, Olivier, Lavenant, Nicolas, Davy, Philippe, Burbey, Thomas J., and Boudin, Frédérick

Subjects

FAULT zones, FLUID mechanics, FLUID pressure

Abstract

Abstract: 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. [ABSTRACT FROM AUTHOR]

Published

2017

10. Combining periodic hydraulic tests and surface tilt measurements to explore in situ fracture hydromechanics.

Author

Schuite, Jonathan, Longuevergne, Laurent, Bour, Olivier, Guihéneuf, Nicolas, Becker, Matthew W., Cole, Matthew, Burbey, Thomas J., Lavenant, Nicolas, and Boudin, Frédéric

Abstract

Fractured bedrock reservoirs are of socio-economical importance, as they may be used for storage or retrieval of fluids and energy. In particular, the hydromechanical behavior of fractures needs to be understood as it has implications on flow and governs stability issues (e.g., microseismicity). Laboratory, numerical, or field experiments have brought considerable insights to this topic. Nevertheless, in situ hydromechanical experiments are relatively uncommon, mainly because of technical and instrumental limitations. Here we present the early stage development and validation of a novel approach aiming at capturing the integrated hydromechanical behavior of natural fractures. It combines the use of surface tiltmeters to monitor the deformation associated with the periodic pressurization of fractures at depth in crystalline rocks. Periodic injection and withdrawal advantageously avoids mobilizing or extracting significant amounts of fluid, and it hinders any risk of reservoir failure. The oscillatory perturbation is intended to (1) facilitate the recognition of its signature in tilt measurements and (2) vary the hydraulic penetration depth in order to sample different volumes of the fractured bedrock around the inlet and thereby assess scale effects typical of fractured systems. By stacking tilt signals, we managed to recover small tilt amplitudes associated with pressure-derived fracture deformation. Therewith, we distinguish differences in mechanical properties between the three tested fractures, but we show that tilt amplitudes are weakly dependent on pressure penetration depth. Using an elastic model, we obtain fracture stiffness estimates that are consistent with published data. Our results should encourage further improvement of the method. [ABSTRACT FROM AUTHOR]

Published

2017

11. Electrical resistivity imaging of hydrologic flow through surface coal mine valley fills with comparison to other landforms.

Author

Greer, Breeyn M., Burbey, Thomas J., Zipper, Carl E., and Hester, Erich T.

Subjects

STRIP mining, WATER quality, UNDERGROUND areas, HYDROLOGIC cycle

Abstract

Surface coal mining has altered land cover, near-surface geologic structure, and hydrologic processes of large areas in central Appalachia, USA. These alterations are associated with changes in water quality such as elevated total-dissolved solids, which is usually measured via its surrogate, specific conductance (SC). The SC of valley fill effluent streams is a function of fill construction methods, materials, and age; yet hydrologic studies that relate these variables to water quality are sparse due to the difficulty of conducting traditional hydrologic studies in mined landscapes. We used electrical resistivity imaging (ERI) to visualize the subsurface geologic structure and hydrologic flow paths within a valley fill. ERI is a noninvasive geophysical technique that maps spatiotemporal changes in resistivity of the subsurface. We paired ERI with artificial rainfall experiments to track infiltrated water as it moved through the valley fill. Results indicate that ERI can be used to identify subsurface geologic structure and track advancing wetting fronts or preferential flow paths. Our results suggest that the upper portion of the fill contains significant fines, whereas the deeper profile is primarily large rocks and void spaces. Water tended to pond on the surface of compacted areas until it reached preferential flow paths, where it appeared to infiltrate quickly down to >15 m depth in 75 min. ERI applications can improve understanding of how fill construction techniques influence subsurface water movement, and in turn may aid in the development of valley fill construction methods to reduce water quality effects. [ABSTRACT FROM AUTHOR]

Published

2017

12. Inverse modelling using PS-InSAR data for improved land subsidence simulation in Las Vegas Valley, Nevada.

Author

Zhang, Meijing and Burbey, Thomas J.

Subjects

CALIBRATION, EARTH movements, HYDRAULIC models, ELECTRIC admittance, LAND subsidence

Abstract

Las Vegas Valley has had a long history of groundwater development and subsequent surface deformation. InSAR interferograms have revealed detailed and complex spatial patterns of subsidence in the Las Vegas Valley area that do not coincide with major pumping regions. This research represents the first effort to use high spatial and temporal resolution subsidence observations from InSAR and hydraulic head data to inversely calibrate transmissivities ( T), elastic and inelastic skeletal storage coefficients ( Ske and Skv) of the developed-zone aquifer and conductance ( CR) of the basin-fill faults for the entire Las Vegas basin. The results indicate that the subsidence observations from InSAR are extremely beneficial for accurately quantifying hydraulic parameters, and the model calibration results are far more accurate than when using only groundwater levels as observations, and just a limited number of subsidence observations. The discrepancy between distributions of pumping and greatest levels of subsidence is found to be attributed to spatial variations in clay thickness. The Eglington fault separates thicker interbeds to the northwest from thinner interbeds to the southeast and the fault may act as a groundwater-flow barrier and/or subsidence boundary, although the influence of the groundwater barrier to this area is found to be insignificant. Copyright © 2016 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2016

13. Characterization of a hydraulically induced crystalline-rock fracture.

Author

Burbey, Thomas J. and Brandon, Ryan A.

Subjects

CRYSTALLINE rocks, ROCKS, FRACTURE mechanics, AQUIFERS, HYDROGEOLOGY

Abstract

Hydraulic fracturing has become an important technique for enhancing the permeability of hydrocarbon source rocks and increasing aquifer transmissivity in many hard rock environments where natural fractures are limited, yet little is known about the nature or behaviour of these hydraulically induced fractures as conduits to flow and transport. We propose that these fractures tend to be smooth based on observed hydraulic and transport behaviour. In this investigation a multi-faceted approach was used to quantify the properties and characteristics of an isolated hydraulically induced fracture in crystalline rocks. Packers were used to isolate the fracture that is penetrated by two separate observation wells located approximately 33 m apart. A series of aquifer tests and an induced gradient tracer test were performed to better understand the nature of this fracture. Aquifer test results indicate that full recovery is slow because of the overall low permeability of the crystalline rocks. Drawdown tests indicate that the fracture has a transmissivity of 1-2 m2/day and a specific storage on the order of 2-9 × 10−7/m. Analysis of a potassium-bromide tracer test break through curve shows classic Fickian behaviour with minimal tailing analogous to parallel plate flow. Virtually all of the tracer was recovered, and the breakthrough curve dilution indicates that the swept area is only about 11% of a radial flow field and the estimated aperture is ≤0.5 mm, which implies a narrow linear flow region. These outcomes suggest that transport within these hydraulically induced 'smooth' fractures in crystalline rocks is rapid with minimal mixing, small local velocity fluctuations and no apparent diffusion into the host rock or secondary fractures. Copyright © 2016 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2016

14. A Comparison of Three Hydraulic Parameter Optimization Schemes for Las Vegas Valley.

Author

MEIJING ZHANG and BURBEY, THOMAS J.

Subjects

DEFORMATION of surfaces, HYDRAULICS, HYDROGEOLOGICAL modeling, COMPARATIVE studies, MATHEMATICAL optimization

Abstract

Las Vegas Valley has had a long history of groundwater development and subsequent surface deformation. Much research has been done to estimate parameters within the Las Vegas Basin, but this research represents the first effort to use parameter estimation techniques to inversely calibrate hydrogeologic aquifer parameters for the principal aquifer of the entire basin. Three different inversion strategies are invoked to determine the most accurate and computationally efficient method for estimating transmissivities T and elastic and inelastic skeletal storage coefficients (Ske and Skr) at the basin scale: the zonation method (ZM), the adaptive multi-scale method, and the differential evolution adaptive metropolis Markov chain Monte Carlo scheme (DREAM MCMC). The three inversion methods are compared and contrasted based on quantitative measurements of model fit, computational efficiency, and user flexibility. The results indicate that overall, the adaptive multi-scale method, which is able to efficiently reconstruct the T, Ske, and Skv zones while providing more flexibility and accuracy than the other two methods, is the best strategy for calibrating optimal model parameters and providing a framework for developing an accurate hydrogeologic model for Las Vegas Valley. [ABSTRACT FROM AUTHOR]

Published

2016

15. Numerical modeling of percolating flow path in a caprock formation during aquifer pressurization and its implication for CO2 sequestration.

Author

Xuejun Zhou and Burbey, Thomas J.

Subjects

CAP rock, WASTE disposal sites, AQUIFERS, SAND bars, FLUID injection, FLUID flow

Abstract

Spatial distribution of sand bodies in caprock is important to its sealing potential in the evaluation of a potential waste disposal site. A numerical investigation was conducted to investigate the roles of sand bodies in caprock integrity, and a new leaking mechanism associated with the embedded sand bodies has been identified for the first time. This numerical model is characterized by a low proportion of sand bodies in caprock formation and stochastic permeability assignments to the shale facies with a consideration of stress-sensitive permeability. The research revealed that sand bodies in caprock, even initially unconnected due to their low concentration, represent the foundation for creating a percolating flow path if certain conditions are met. These conditions include a relatively high pore pressure gradient across the caprock, which may occur during fluid injection and a favorable geometric configuration of these sand bodies. Sand bodies of different shapes play different roles in forming a percolating flow path. Sand bars/dykes can lead pore pressure front to cover a considerable vertical thickness quickly, while thin sand sheets tend to transfer the pore pressure front across a large horizontal range and thus increase the possibility of involving other local sand bodies in the evolution of percolating flow paths. On the other hand, the presence of percolating flow path in caprock can limit the pore pressure increase in the aquifer formation during fluid injection. The more active the flow paths, the less increase the pore pressure that occurs in the aquifer. Stress-dependent permeability can facilitate the formation of percolating flow path, but evaluating how much impact it may have remains a question for future research. The modeling results indicate that the underlying geologically based discrete structure of permeable domains, even when masked by a lowpermeable rock matrix, exerts a significant influence on the location and magnitude of fluid flow within the system during fluid injection. [ABSTRACT FROM AUTHOR]

Published

2016

16. A New Zonation Algorithm with Parameter Estimation Using Hydraulic Head and Subsidence Observations.

Author

Zhang, Meijing, Burbey, Thomas J., Nunes, Vitor Dos Santos, and Borggaard, Jeff

Subjects

PARAMETER estimation, INTERTIDAL zonation, GROUNDWATER ecology, AQUIFER storage recovery, HYDRAULIC machinery, APERTURE antennas

Abstract

Parameter estimation codes such as UCODE_2005 are becoming well-known tools in groundwater modeling investigations. These programs estimate important parameter values such as transmissivity ( T) and aquifer storage values ( Sa) from known observations of hydraulic head, flow, or other physical quantities. One drawback inherent in these codes is that the parameter zones must be specified by the user. However, such knowledge is often unknown even if a detailed hydrogeological description is available. To overcome this deficiency, we present a discrete adjoint algorithm for identifying suitable zonations from hydraulic head and subsidence measurements, which are highly sensitive to both elastic ( Sske) and inelastic ( Sskv) skeletal specific storage coefficients. With the advent of interferometric synthetic aperture radar ( InSAR), distributed spatial and temporal subsidence measurements can be obtained. A synthetic conceptual model containing seven transmissivity zones, one aquifer storage zone and three interbed zones for elastic and inelastic storage coefficients were developed to simulate drawdown and subsidence in an aquifer interbedded with clay that exhibits delayed drainage. Simulated delayed land subsidence and groundwater head data are assumed to be the observed measurements, to which the discrete adjoint algorithm is called to create approximate spatial zonations of T, Sske, and Sskv. UCODE-2005 is then used to obtain the final optimal parameter values. Calibration results indicate that the estimated zonations calculated from the discrete adjoint algorithm closely approximate the true parameter zonations. This automation algorithm reduces the bias established by the initial distribution of zones and provides a robust parameter zonation distribution. [ABSTRACT FROM AUTHOR]

Published

2014

17. An Integrated Risk Assessment Model of Township-Scaled Land Subsidence Based on an Evidential Reasoning Algorithm and Fuzzy Set Theory.

Author

Chen, Yu, Shu, Longcang, and Burbey, Thomas J.

Subjects

RISK assessment, LAND subsidence, DECISION making methodology, FUZZY sets, PSYCHOLOGICAL vulnerability, DEMPSTER-Shafer theory

Abstract

Land subsidence risk assessment (LSRA) is a multi-attribute decision analysis (MADA) problem and is often characterized by both quantitative and qualitative attributes with various types of uncertainty. Therefore, the problem needs to be modeled and analyzed using methods that can handle uncertainty. In this article, we propose an integrated assessment model based on the evidential reasoning (ER) algorithm and fuzzy set theory. The assessment model is structured as a hierarchical framework that regards land subsidence risk as a composite of two key factors: hazard and vulnerability. These factors can be described by a set of basic indicators defined by assessment grades with attributes for transforming both numerical data and subjective judgments into a belief structure. The factor-level attributes of hazard and vulnerability are combined using the ER algorithm, which is based on the information from a belief structure calculated by the Dempster-Shafer (D-S) theory, and a distributed fuzzy belief structure calculated by fuzzy set theory. The results from the combined algorithms yield distributed assessment grade matrices. The application of the model to the Xixi-Chengnan area, China, illustrates its usefulness and validity for LSRA. The model utilizes a combination of all types of evidence, including all assessment information-quantitative or qualitative, complete or incomplete, and precise or imprecise-to provide assessment grades that define risk assessment on the basis of hazard and vulnerability. The results will enable risk managers to apply different risk prevention measures and mitigation planning based on the calculated risk states. [ABSTRACT FROM AUTHOR]

Published

2014

18. Poroelastic Effects on Fracture Characterization.

Author

Burbey, Thomas J.

Subjects

WATER levels, PRECIPITATION anomalies, URANIUM & the environment, POROELASTICITY, GROUNDWATER analysis, HYDRAULICS -- Environmental aspects

Abstract

Reverse water-level fluctuations have been widely observed in aquitards or aquifers separated from a pumped confined aquifer (Noordbergum effect) immediately after the initiation of pumping. This same reverse fluctuation has been observed in a fractured crystalline-rock aquifer at the Coles Hill uranium site in Virginia in which the reverse water-level response occurs within a pumped fracture and results from an instantaneous strain response to pumping that precedes the pore-pressure response in observation wells of sufficient distance from the pumped well. This response is referred to as the Mandel-Cryer effect. The unique aspect of this water level rise during a controlled 24 h pumping test was that the reverse water levels lasted for approximately 100 min and reached a magnitude of nearly 1 cm prior to a typical drawdown response. The duration and magnitude of the response reflects the poromechanical properties of the fractured host rock and hydraulic properties of the pumped fracture. An axisymmetric flow and deformation model were developed using Biot2 in an effort to simulate the observed water-level response along an assumed 0.5 to 1.0 cm aperture horizontal fracture 176 m from the pumping well and to identify the importance of the poroelastic effect. Results indicate that traditional aquifer-testing methods that ignore the poromechanical response are not significantly different than results that include the response. However, the poroelastic effect allows for more accurate and efficient parameter calibration. [ABSTRACT FROM AUTHOR]

Published

2013

19. Composite Subsidence Vulnerability Assessment Based on an Index Model and Index Decomposition Method.

Author

Chen, Yu, Shu, Longcang, and Burbey, Thomas J.

Subjects

PSYCHOLOGICAL vulnerability, BUILDING protection, DECISION making, WATER management, WATER supply

Abstract

The threat of damage to buildings and other infrastructures resulting from land subsidence associated with groundwater pumping in urbanized areas is an ongoing problem requiring assessment. An important goal of subsidence vulnerability assessment is to construct a composite subsidence vulnerability index (SVI) that is represented by a set of indicators that focuses on four different thematic factors: physical, social, economic, and environmental vulnerability. These indicators are evaluated on the basis of indicator selection principles and then weighted by their contribution rate to the overall index. The weights reflect different measures assigned to the township-specific conditions. A complete and composite subsidence vulnerability assessment is developed in which future vulnerability management decision-making processes can be readily made. The vulnerability assessment includes not only the construction of the SVI, which involves selecting, assigning value to, weighting, and aggregating the vulnerability indicators, but also the presentation of the SVI decomposition. Research results demonstrate that a composite subsidence vulnerability assessment method can be made by first constructing and then decomposition-presenting the overall SVI. This allows for the relative comparison of subsidence vulnerability and the identification of the main vulnerable indicators; thus providing subsidence risk, which represents an important step toward vulnerability management of water resources. [ABSTRACT FROM PUBLISHER]

Published

2013

20. Assessing Hydrofracing Success from Earth Tide and Barometric Response.

Author

Burbey, Thomas J. and Meijing Zhang

Subjects

EARTH tides, ATMOSPHERIC pressure, WATER levels, METHODOLOGY

Abstract

Identifying fracture pathways and connectivity between adjacent wells is vital for understanding flow characteristics, transport properties, and fracture characteristics. In this investigation, a simple, straightforward methodology is presented for assessing hydrofracing success and identifying possible fracture connectivity between neighboring boreholes, using water-level barometric response and tide signatures of individual fractures in a crystalline-rock setting. Water levels and barometric pressure heads were collected at two wells 27 m apart both prior to, and after, hydrofracing one of the wells at the fractured-rock research site in Floyd County, Virginia. Vastly different barometric and tidal signatures existed at the two wells prior to hydrofracing as well EX-1 had no discernable fractures, while W-03 was connected to an identified fault-zone aquifer and produced a notable water-level earth tide and barometric signatures. After hydrofracing EX-1, new fractures were induced and the resulting water-level tidal signature and barometric efficiencies were nearly identical to the W-03 well. Aquifer testing conducted from both wells verified this connectivity along the fault-zone aquifer. The small phase difference between the tidal responses in the two wells can be accounted for by the calculated differences in transmissivity and casing diameter. [ABSTRACT FROM AUTHOR]

Published

2010

21. The Value of Subsidence Data in Ground Water Model Calibration.

Author

Yan, Tingting and Burbey, Thomas J.

Subjects

AQUIFERS, GROUNDWATER research, CALIBRATION, HYDRAULIC engineering, PARAMETER estimation, ESTIMATION theory, GLOBAL Positioning System, COHERENT radar, RECLAMATION of land

Abstract

The accurate estimation of aquifer parameters such as transmissivity and specific storage is often an important objective during a ground water modeling investigation or aquifer resource evaluation. Parameter estimation is often accomplished with changes in hydraulic head data as the key and most abundant type of observation. The availability and accessibility of global positioning system and interferometric synthetic aperture radar data in heavily pumped alluvial basins can provide important subsidence observations that can greatly aid parameter estimation. The aim of this investigation is to evaluate the value of spatial and temporal subsidence data for automatically estimating parameters with and without observation error using UCODE-2005 and MODFLOW-2000. A synthetic conceptual model (24 separate cases) containing seven transmissivity zones and three zones each for elastic and inelastic skeletal specific storage was used to simulate subsidence and drawdown in an aquifer with variably thick interbeds with delayed drainage. Five pumping wells of variable rates were used to stress the system for up to 15 years. Calibration results indicate that (1) the inverse of the square of the observation values is a reasonable way to weight the observations, (2) spatially abundant subsidence data typically produce superior parameter estimates under constant pumping even with observation error, (3) only a small number of subsidence observations are required to achieve accurate parameter estimates, and (4) for seasonal pumping, accurate parameter estimates for elastic skeletal specific storage values are largely dependent on the quantity of temporal observational data and less on the quantity of available spatial data. [ABSTRACT FROM AUTHOR]

Published

2008

22. The Influence of Geologic Structures on Deformation due to Ground Water Withdrawal.

Author

Burbey, Thomas J.

Subjects

GROUNDWATER, WATER, HYDROGEOLOGY, GROUNDWATER monitoring, GROUNDWATER acidification, HYDRAULIC control systems, FLUID power technology, FINITE element method, WATER supply

Abstract

A 62 day controlled aquifer test was conducted in thick alluvial deposits at Mesquite, Nevada, for the purpose of monitoring horizontal and vertical surface deformations using a high-precision global positioning system (GPS) network. Initial analysis of the data indicated an anisotropic aquifer system on the basis of the observed radial and tangential deformations. However, new InSAR data seem to indicate that the site may be bounded by an oblique normal fault as the subsidence bowl is both truncated to the northwest and offset from the pumping well to the south. A finite-element numerical model was developed using ABAQUS to evaluate the potential location and hydromechanical properties of the fault based on the observed horizontal deformations. Simulation results indicate that for the magnitude and direction of motion at the pumping well and at other GPS stations, which is toward the southeast (away from the inferred fault), the fault zone (5 m wide) must possess a very high permeability and storage coefficient and cross the study area in a northeast-southwest direction. Simulated horizontal and vertical displacements that include the fault zone closely match observed displacements and indicate the likelihood of the presence of the inferred fault. This analysis shows how monitoring horizontal displacements can provide valuable information about faults, and boundary conditions in general, in evaluating aquifer systems during an aquifer test. [ABSTRACT FROM AUTHOR]

Published

2008

23. Influence of Ancient Thrust Faults on the Hydrogeology of the Blue Ridge Province.

Author

Seaton, William J. and Burbey, Thomas J.

Subjects

THRUST faults (Geology), GEOLOGIC faults, GROUNDWATER, CHLOROFLUOROCARBONS, HYDROLOGY

Abstract

The Blue Ridge Province contains ubiquitous northeast-southwest--trending thrust faults or smaller thrust "slivers" that greatly impact the nature and character of ground water flow in this region. Detailed investigations at a field site in Floyd County, Virginia, indicate that high-permeability zones occur in the brittle crystalline rocks above these thrust faults. Surface and borehole geophysics, aquifer tests, and chlorofluorocarbon and geochemical data reveal that the shallow saprolite aquifer is separated from the deeper fault-zone aquifer by a low-fracture permeability bedrock confining unit, the hydraulic conductivity of which has been estimated to be six orders of magnitude less than the conductivity of the fault zones at the test site. Within the Blue Ridge Province, these fault zones can occur at depths of 300 m or more, can contain a significant amount of storage, and yield significant quantities of water to wells. Furthermore, it is expected that these faults may compartmentalize the deep aquifer system. Recharge to and discharge from the deep aquifer occurs by slow leakage through the confining unit or through localized breach zones that occur where quartz accumulated in high concentrations during metamorphism and later became extensively fractured during episodes of deformation. The results of this investigation stress the importance of thrust faults in this region and suggest that hydrogeologic models for the Blue Ridge Province include these ancient structural features. Faults in crystalline-rock environments may not only influence the hydrology, they may dominate the flow characteristics of a region. [ABSTRACT FROM AUTHOR]

Published

2005

24. CHARACTERIZATION OF GROUND WATER FLOW FROM SPRING DISCHARGE IN A CRYSTALLINE ROCK ENVIRONMENT.

Author

Gentry, W. Miles and Burbey, Thomas J.

Subjects

GROUNDWATER, HYDROGEOLOGY, HYDROLOGY, AQUIFERS, WATER quality

Abstract

Recent investigations describing the hydrogeology of the Blue Ridge Province of Virginia suggest the occurrence of multiple aquifers and flow paths that may be responsible for the variable flow behavior of springs and seeps appearing throughout the region. Deep, confined aquifers associated with ubiquitous faults and shallow, variably confined saprolite aquifers may contribute water to spring outlets resulting in significantly different quantities of discharge and water quality. Multiple analyses are required to adequately identify the flow paths to springs. In this investigation, hydrograph analyses, surface electrical resistivity surveys, aquifer tests, and nitrate concentrations are used in conjunction with previously reported analyses from borehole logs and age dating of ground water to identify two distinct flow paths. Results indicate that base flow occurs from a deep fault zone aquifer and such discharge can be maintained even during prolonged periods of drought, while increased discharge identified on hydrograph peaks suggests the occurrence of rapid flow through the saprolite aquifer within a radius of about 25 meters of the spring orifice. Springflow hydrograph analysis is suitable for rapid characterization of flow paths leading to spring outlets. Rapid characterization is important for evaluation of potential water quality problems arising from contamination of shallow and deep aquifers and for evaluation of water resource susceptibility to drought. The techniques evaluated here are suitable for use in other locations in fractured crystalline rock environments. [ABSTRACT FROM AUTHOR]

Published

2004

25. Multiple-Aquifer Characterization from Single Borehole Extensometer Records.

Author

Pope, Jason P. and Burbey, Thomas J.

Subjects

AQUIFERS, HYDROGEOLOGY, WATER levels, HYDRAULIC measurements, LAND subsidence, EXTENSOMETER

Abstract

Measurement and analysis of aquifer-system compaction have been used to characterize aquifer and confining unit properties when other techniques such as flow modeling have been ineffective at adequately quantifying storage properties or matching historical water levels in environments experiencing land subsidence. In the southeastern coastal plain of Virginia, high-sensitivity borehole pipe extensometers were used to measure 24.2 mm of total compaction at Franklin from 1979 through 1995 (1.5 mm/year) and 50.2 mm of total compaction at Suffolk from 1982 through 1995 (3.7 mm/year). Analysis of the extensometer data reveals that the small rates of aquifer-system compaction appear to be correlated with withdrawals of water from confined aquifers. One-dimensional vertical compaction modeling indicates measured compaction is the result of nonrecoverable hydrodynamic consolidation of the fine-grained confining units and interbeds, as well as recoverable compaction and expansion of coarse-grained aquifer units. The calibrated modeling results indicate that nonrecoverable specific storage values decrease with depth and range from 1.5 x 10[sup-5]/m for aquifer units to 1.5 x 10[sup-4]/m for confining units and interbeds. The aquifer and Potomac system recoverable specific storage values were all estimated to be 4.5 x 10[sup-6]/m, while the confining units and interbeds had values of 6.0 x 10[sup-6]/m. The calibrated vertical hydraulic conductivity values of the confining units and interbeds ranged from 6.6 x 10[sup-4]m/year to 2.0 x 10[sup-3]m/year. These parameter values will be useful in future management and modeling of ground water in the Virginia Coastal Plain. [ABSTRACT FROM AUTHOR]

Published

2004

26. Storage Coefficient Revisited: Is Purely Vertical Strain a Good Assumption?

Author

Burbey, Thomas J.

Subjects

STRAINS & stresses (Mechanics), AQUIFERS, GROUNDWATER

Abstract

Evaluates the validity of the assumption that horizontal strain is negligible during pumping in confined elastic aquifer systems. Quantitative definition of the groundwater storage coefficient; Conceptualization of the Theis-type aquifer; Results using volume strain and strain components; Porosity considerations.

Published

2001

27. Stress-Strain Analyses for Aquifer-System Characterization.

Author

Burbey, Thomas J.

Subjects

STRESS-strain curves, AQUIFERS, LAND subsidence, MATHEMATICAL models

Abstract

Investigates stress-strain diagrams numerically to determine the usefulness of subsidence information for calculating the skeletal storage of the aquifer system. Discussion on subsidence modeling; Stress-strain relations under nonrecoverable and recoverable conditions; Contribution for horizontal strain.

Published

2001

28. HYDROLOGIC ANALYSIS OF DISCHARGE SUSTAINABILITY FROM AN ABANDONED UNDERGROUND COAL MINE.

Author

Burbey, Thomas J., Younos, Tamim, and Anderson, Eric T.

Abstract

BSTRACT: Discharge from flooded abandoned subsurface coal mines is considered a potential source for water supplies where other acceptable water sources are not available. The objective of this study was to develop procedures for determining sustainability of mine-water discharge using rainfall and discharge data for a case study site. The study site is located in southwest Virginia where Late Paleozoic sequences of sandstone, coal, and shale predominate. A rain gauge and a flow rate monitoring system were installed at the site and data were collected for a period of 100 days. The recording period corresponded with one of the driest periods in recent years and, therefore, provided valuable information regarding the flow sustainability during baseflow conditions. From available data on underground mining patterns, geology, and ground water flow regimes, it was determined that a coal mine aquifer exhibits hydraulic characteristics very similar to the extremely heterogeneous systems observed in karst aquifers, and the mine discharge is analogous to springflow. Thus, techniques commonly used in karst-water systems and springflow analysis were used to develop rainfall/mine-discharge relationships. Springflow recession analysis was performed on five rainfall recessions and the coefficient for each recession was compared and interpreted in light of known geologic information. It was found that the recession coefficients described the mine discharge adequately and the mine aquifer response to a rainfall pulse was very similar to the response from certain types of karst aquifers. A cross-correlation analysis was performed to verify the results of the recession analysis and to develop a 'black box' statistical model for discharge data. The correlation analysis proved the validity of springflow recession analysis for mine discharge. The recorded data length was not adequate to create a statistical model, however, but a procedure was proposed for a statistical model that could be used with large flow records. For the study site, the mine discharge was found to be sustainable for a prolonged period of time. [ABSTRACT FROM AUTHOR]

Published

2000

29. Evaluation of subsurface infiltration and displacement in a subsidence-reactivated normal fault in the Aguascalientes Valley, Mexico.

Author

Hernandez-Marin, Martin, Pacheco-Martínez, Jesús, Burbey, Thomas J., Carreón-Freyre, Dora C., Ochoa-González, Gil H., Campos-Moreno, Guillermo E., and de Lira-Gómez, Pedro

Subjects

ELECTRICAL resistivity, LAND subsidence, FLUID mechanics, FAULT zones

Abstract

In this study, the main hydromechanical characteristics of a portion of the Oriente fault, in the valley of Aguascalientes, Mexico, are analyzed and discussed. This discontinuity corresponds to a normal fault that was originated before the formation of the Aguascalientes graben. However, its recent activity and potential reactivation may be directly linked to the land subsidence currently occurring in the center of the valley. A 1-year campaign to monitor deformation in two transects perpendicular to this fault indicates continuous deformation activity with maximum vertical descending values of 43 mm in the hanging wall. On the other hand, a fieldwork procedure to determine the geologic structure of the fault zone and to establish the infiltration patterns of a selected point in the fault was performed as well. This field test consisted of analyzing the resistivity patterns of profiles across and along the fault, implemented before, during and after pouring groundwater into the fault and monitoring the fluids movement through the fault zone. Results suggest that the fault contains three perpendicular fault branches in a distance of 80 m, portraying a potential domino fault system. The high infiltration capacity of the fault opening allowed the rapid intrusion of water into the subsoil, and the distinguishable changes in electrical resistivity in the profiles parallel to the fault plane suggest that the infiltrating water goes down into the soil through the fault plane or adjacent to it. [ABSTRACT FROM AUTHOR]

Published

2017