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Author: Yi Liu Publisher: ISBN: Category : Civil engineering Languages : en Pages : 346
Book Description
Land subsidence attributable to the compaction (consolidation) of aquifer systems is recognized to be a geological hazard. It is an environmental consequence of groundwater withdrawal in many cities and other areas worldwide. Prediction of land subsidence due to subsurface fluid withdrawal (whether the fluid is oil, gas, water, stream, or geopressure brine) depends on the quantitative identification of parameters for a selected theoretical model. A new inverse algorithm (InvCOMPAC) for finding transient land subsidence parameters due to the combined compression and expansion of one or more confined aquifer systems in response to ground fluid withdrawal is developed in this dissertation. It consists of combining the Newton-Raphson adjustment algorithm and Helm's one-dimensional finite-difference compaction (or consolidation) model (COMPAC). The subsidence (or consolidation) model can be replaced by any appropriate model. This inverse code (or algorithm) identifies five parameters that control transient land subsidence at a site of interest: vertical hydraulic conductivity of compressible aquitards, K', nonrecoverable S' skv, and recoverable S'ske specific storage of the aquitards, specific storage of the aquifer, S S, and an initial vertical distribution, p' max0, of maximum past preconsolidation pressure within the confined aquifer system. For computational convenience, p'max0 may or may not be considered to be uniform. K', S'skv, S'ske, and S S are constants for the constant-parameter option or indicate only the initial values for the stress-dependent parameter option of Helm's model. An initial set of estimated values for these five parameters is found to be necessary in order to apply the inverse algorithm to an idealized compressible confined aquifer system. A new graphical-analytic method is introduced for estimating a realistic initial set of these values. The idealized data for developing this method is from COMPAC's calculation of compression and expansion in response to both long-term nondeclining sinusoidal boundary stress and also long-term declining sinusoidal boundary stress. This methodology is based on delay time constants of clay consolidation, the elastic hysteresis loop of clay stress-strain relationships, and Darcy's law. An investigation of this idealized model shows that the relative error of these five parameters found by applying the inverse model to calculated compaction using initial values of the parameters simply obtained from this methodology is 1.2∼6.3%. (Abstract shortened by UMI.). -- Abstract.
Author: Yi Liu Publisher: ISBN: Category : Civil engineering Languages : en Pages : 346
Book Description
Land subsidence attributable to the compaction (consolidation) of aquifer systems is recognized to be a geological hazard. It is an environmental consequence of groundwater withdrawal in many cities and other areas worldwide. Prediction of land subsidence due to subsurface fluid withdrawal (whether the fluid is oil, gas, water, stream, or geopressure brine) depends on the quantitative identification of parameters for a selected theoretical model. A new inverse algorithm (InvCOMPAC) for finding transient land subsidence parameters due to the combined compression and expansion of one or more confined aquifer systems in response to ground fluid withdrawal is developed in this dissertation. It consists of combining the Newton-Raphson adjustment algorithm and Helm's one-dimensional finite-difference compaction (or consolidation) model (COMPAC). The subsidence (or consolidation) model can be replaced by any appropriate model. This inverse code (or algorithm) identifies five parameters that control transient land subsidence at a site of interest: vertical hydraulic conductivity of compressible aquitards, K', nonrecoverable S' skv, and recoverable S'ske specific storage of the aquitards, specific storage of the aquifer, S S, and an initial vertical distribution, p' max0, of maximum past preconsolidation pressure within the confined aquifer system. For computational convenience, p'max0 may or may not be considered to be uniform. K', S'skv, S'ske, and S S are constants for the constant-parameter option or indicate only the initial values for the stress-dependent parameter option of Helm's model. An initial set of estimated values for these five parameters is found to be necessary in order to apply the inverse algorithm to an idealized compressible confined aquifer system. A new graphical-analytic method is introduced for estimating a realistic initial set of these values. The idealized data for developing this method is from COMPAC's calculation of compression and expansion in response to both long-term nondeclining sinusoidal boundary stress and also long-term declining sinusoidal boundary stress. This methodology is based on delay time constants of clay consolidation, the elastic hysteresis loop of clay stress-strain relationships, and Darcy's law. An investigation of this idealized model shows that the relative error of these five parameters found by applying the inverse model to calculated compaction using initial values of the parameters simply obtained from this methodology is 1.2∼6.3%. (Abstract shortened by UMI.). -- Abstract.
Author: E.C. Donaldson Publisher: Elsevier ISBN: 0080542093 Category : Science Languages : en Pages : 519
Book Description
Subsidence of geologic surface structures due to withdrawal of fluids from aquifers and petroleum reservoirs is a phenomenon experienced throughout the world as the demand for water and hydrocarbons increases with increasing population growth. This book addresses the definition and theories of subsidence, and the influences of unique conditions on subsidence; it includes discussions of specific field cases and a basic mathematical model of reservoir compaction and accompanying loss of porosity and permeability. The book is designed as a reference for readers giving immediate access to the geological events that establish conditions for compaction, the mathematical theories of compaction and subsidence, and practical considerations of field case histories in various regions of the world.
Author: American Society of Civil Engineers Publisher: ISBN: 9780784415702 Category : Groundwater Languages : en Pages : 260
Book Description
Investigation of Land Subsidence due to Fluid Withdrawal provides a detailed overview of the occurrence and control of land subsidence due to fluid withdrawal.
Author: American Society of Civil Engineers Publisher: ISBN: 9780784484081 Category : Groundwater Languages : en Pages : 239
Book Description
"Investigation of Land Subsidence due to Fluid Withdrawal provides a detailed look overview of the occurrence and control of land subsidence due to fluid withdrawal"--
Author: Paul Inkenbrandt Publisher: Utah Geological Survey ISBN: 1557918910 Category : Base flow (Hydrology). Languages : en Pages : 122
Book Description
This 116-page report presents the results of an investigation by the Utah Geological Survey of land subsidence and earth fissures in Cedar Valley, Iron County, Utah. Basin-fill sediments of the Cedar Valley Aquifer contain a high percentage of fine-grained material susceptible to compaction upon dewatering. Groundwater discharge in excess of recharge (groundwater mining) has lowered the potentiometric surface in Cedar Valley as much as 114 feet since 1939. Groundwater mining has caused permanent compaction of fine-grained sediments of the Cedar Valley aquifer, which has caused the land surface to subside, and a minimum of 8.3 miles of earth fissures to form. Recently acquired interferometric synthetic aperture radar imagery shows that land subsidence has affected approximately 100 mi² in Cedar Valley, but a lack of accurate historical benchmark elevation data over much of the valley prevents its detailed quantification. Continued groundwater mining and resultant subsidence will likely cause existing fissures to lengthen and new fissures to form which may eventually impact developed areas in Cedar Valley. This report also includes possible aquifer management options to help mitigate subsidence and fissure formation, and recommended guidelines for conducting subsidence-related hazard investigations prior to development.
Author: Yi Liu
Author: Yi Liu
Author: E.C. Donaldson
Author: American Society of Civil Engineers
Author: American Society of Civil Engineers
Author: Panel on Land Subsidence
Author: 
Author: Geological Survey (U.S.)
Author: Sharon E. Kroening
Author: Paul Inkenbrandt
Author: Alex K. Williamson