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Author: Hyung Jun Yang
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Quantitative predictions of fluid flow and transport in porous media are often compromised by multi-scale heterogeneity and insufficient site characterization. These factors introduce uncertainty on the input and output of physical systems which are generally expressed as partial differential equations (PDEs). The characterization of this predictive uncertainty is typically done with forward propagation of input uncertainty as well as inverse modeling for the dynamic data integration. The main challenges of forward uncertainty propagation arise from the slow convergence of Monte Carlo Simulations (MCS) especially when the goal is to compute the probability distribution which is necessary for risk assessment and decision making under uncertainty. On the other hand, reliable inverse modeling is often hampered by the ill-posedness of the problem, thus the incorporation of geological constraints becomes increasingly important. In the thesis, four significant contributions are made to alleviate these outstanding issues on forward and inverse problems. First, the method of distributions for the steady-state flow problem is developed to yield a full probabilistic description of outputs via probability distribution function (PDF) or cumulative distribution (CDF). The derivation of deterministic equation for CDF relies on stochastic averaging techniques and self-consistent closure approximation which ensures the resulting CDF has the same mean and variance as those computed with moment equations or MCS. We conduct a series of numerical experiments dealing with steady-state two-dimensional flow driven by either a natural hydraulic head gradient or a pumping well. These experiments reveal that the proposed method remains accurate and robust for highly heterogeneous formations with the variance of log conductivity as large as five. For the same accuracy, it is also up to four orders of magnitude faster than MCS with a required degree of confidence. The second contribution of this work is the extension of the distribution-based method to account for uncertainty in the geologic makeup of a subsurface environment and non-stationary cases. Our CDF-RDD framework provides a probabilistic assessment of uncertainty in highly heterogeneous subsurface formations by combining the method of distributions and the random domain decomposition (RDD). Our numerical experiments reveal that the CDF-RDD remains accurate for two-dimensional flow in a porous material composed of two heterogeneous geo-facies, a setting in which the original distribution method fails. For the same accuracy, the CDF-RDD is an order of magnitude faster than MCS. Next, we develop a complete distribution-based method for the probabilistic forecast of two-phase flow in porous media. The CDF equation for travel time is derived within the efficient streamline-based framework to replace the MCS in the previous FROST method. For getting fast and stable results, we employ numerical techniques including pseudo-time integration, flux-limited scheme, and exponential grid spacing. Our CDF-FROST framework uses the results of the method of distributions for travel time as an input of FROST method. The proposed method provides a probability distribution of saturation without using any sampling-based methods. The numerical tests demonstrate that the CDF-FROST shows good accuracy in estimating the probability distributions of both saturation and travel time. For the same accuracy, it is about 5 and 10 times faster than the previous FROST method and naive MCS, respectively. Lastly, we propose a consensus equilibrium (CE) framework to reconstruct the realistic geological model by the inverse modeling of sparse dynamic data. The optimization-based inversion techniques are integrated with recent machine learning-based methods (e.g., variational auto-encoder and convolutional neural network) by the proposed CE algorithm to capture the complicated geological features. The numerical examples verify that the proposed method well preserves the geological realism, and it efficiently quantifies the uncertainty conditioned on dynamic information.
Author: Hyung Jun Yang
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Quantitative predictions of fluid flow and transport in porous media are often compromised by multi-scale heterogeneity and insufficient site characterization. These factors introduce uncertainty on the input and output of physical systems which are generally expressed as partial differential equations (PDEs). The characterization of this predictive uncertainty is typically done with forward propagation of input uncertainty as well as inverse modeling for the dynamic data integration. The main challenges of forward uncertainty propagation arise from the slow convergence of Monte Carlo Simulations (MCS) especially when the goal is to compute the probability distribution which is necessary for risk assessment and decision making under uncertainty. On the other hand, reliable inverse modeling is often hampered by the ill-posedness of the problem, thus the incorporation of geological constraints becomes increasingly important. In the thesis, four significant contributions are made to alleviate these outstanding issues on forward and inverse problems. First, the method of distributions for the steady-state flow problem is developed to yield a full probabilistic description of outputs via probability distribution function (PDF) or cumulative distribution (CDF). The derivation of deterministic equation for CDF relies on stochastic averaging techniques and self-consistent closure approximation which ensures the resulting CDF has the same mean and variance as those computed with moment equations or MCS. We conduct a series of numerical experiments dealing with steady-state two-dimensional flow driven by either a natural hydraulic head gradient or a pumping well. These experiments reveal that the proposed method remains accurate and robust for highly heterogeneous formations with the variance of log conductivity as large as five. For the same accuracy, it is also up to four orders of magnitude faster than MCS with a required degree of confidence. The second contribution of this work is the extension of the distribution-based method to account for uncertainty in the geologic makeup of a subsurface environment and non-stationary cases. Our CDF-RDD framework provides a probabilistic assessment of uncertainty in highly heterogeneous subsurface formations by combining the method of distributions and the random domain decomposition (RDD). Our numerical experiments reveal that the CDF-RDD remains accurate for two-dimensional flow in a porous material composed of two heterogeneous geo-facies, a setting in which the original distribution method fails. For the same accuracy, the CDF-RDD is an order of magnitude faster than MCS. Next, we develop a complete distribution-based method for the probabilistic forecast of two-phase flow in porous media. The CDF equation for travel time is derived within the efficient streamline-based framework to replace the MCS in the previous FROST method. For getting fast and stable results, we employ numerical techniques including pseudo-time integration, flux-limited scheme, and exponential grid spacing. Our CDF-FROST framework uses the results of the method of distributions for travel time as an input of FROST method. The proposed method provides a probability distribution of saturation without using any sampling-based methods. The numerical tests demonstrate that the CDF-FROST shows good accuracy in estimating the probability distributions of both saturation and travel time. For the same accuracy, it is about 5 and 10 times faster than the previous FROST method and naive MCS, respectively. Lastly, we propose a consensus equilibrium (CE) framework to reconstruct the realistic geological model by the inverse modeling of sparse dynamic data. The optimization-based inversion techniques are integrated with recent machine learning-based methods (e.g., variational auto-encoder and convolutional neural network) by the proposed CE algorithm to capture the complicated geological features. The numerical examples verify that the proposed method well preserves the geological realism, and it efficiently quantifies the uncertainty conditioned on dynamic information.
Author: Michael Presho
Publisher:
ISBN: 9781124293486
Category : Multiscale modeling
Languages : en
Pages : 157
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Book Description
Reservoir fractures, deformation bands, and multiscale heterogeneities are capable of affecting porous media fluid flow in a variety of ways. In terms of fracture effects, we typically encounter an unchanged or increased permeability when considering flow parallel to a fracture, whereas we expect a reduced permeability when considering flow across a deformation band. In considering multiscale heterogeneities, it is important to capture both the fine scale behavior and general trends of related flow scenarios. For the first portion of this dissertation, we assess the effects that deformation bands have on multi-component fluid flow. Under the assumption that the width of a band is a random variable, Monte Carlo simulations can then be performed to obtain statistical representations of the transport quantity in relation to the nature of uncertainty. We introduce a stochastic perturbation model as an alternative to Monte Carlo simulations and compare the results with analytical solutions. For the next topic, we propose a method for efficient solution of pressure equations with multiscale features and randomly perturbed permeability coefficients. We use the multiscale finite element method (MsFEM) as a starting point and mention that the method is intended to be used within a Monte Carlo framework where solutions corresponding to samples of the randomly perturbed data need to be computed. We show that the proposed method converges to the MsFEM solution in the limit for each individual sample of the data. The method is then applied to a standard multi-phase flow problem where a number of permeability samples are constructed for Monte Carlo simulations. We focus our quantities of interest on the Darcy velocity and breakthrough time and quantify their uncertainty by constructing corresponding cumulative distribution functions. In the final portion of the dissertation, we introduce a dual porosity, dual permeability model which accounts for differences in matrix and fracture parameters. Fine scale benchmark solutions are obtained and we perform a comparison between corresponding dual porosity, dual permeability model solutions. In the context of subsurface characterization of fractured reservoirs, we apply the Markov chain Monte Carlo method to the dual porosity, dual permeability model. In doing so, we obtain matrix and fracture permeability fields resulting from a distribution conditioned to dynamic tracer cut data. In all chapters, a number of numerical examples are presented to illustrate the performance of the each approach.
Author: Jia Wei
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
In this dissertation, we focus on the uncertainty quantification problems where the goal is to sample the porous media properties given integrated responses. We first introduce a reduced order model using the level set method to characterize the channelized features of permeability fields. The sampling process is completed under Bayesian framework. We hence study the regularity of posterior distributions with respect to the prior measures. The stochastic flow equations that contain both spatial and random components must be resolved in order to sample the porous media properties. Some type of upscaling or multiscale technique is needed when solving the flow and transport through heterogeneous porous media. We propose ensemble-level multiscale finite element method and ensemble-level preconditioner technique for solving the stochastic flow equations, when the permeability fields have certain topology features. These methods can be used to accelerate the forward computations in the sampling processes. Additionally, we develop analysis-of-variance-based mixed multiscale finite element method as well as a novel adaptive version. These methods are used to study the forward uncertainty propagation of input random fields. The computational cost is saved since the high dimensional problem is decomposed into lower dimensional problems. We also work on developing efficient advanced Markov Chain Monte Carlo methods. Algorithms are proposed based on the multi-stage Markov Chain Monte Carlo and Stochastic Approximation Monte Carlo methods. The new methods have the ability to search the whole sample space for optimizations. Analysis and detailed numerical results are presented for applications of all the above methods.
Author: David Crevillen Garcia
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 10
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Natural porous media are highly heterogeneous and characterized by parameters that are often uncertain due to the lack of sufficient data. This uncertainty (randomness) occurs on a multiplicity of scales. We focus on geologic formations with the two dominant scales of uncertainty: a large-scale uncertainty in the spatial arrangement of geologic facies and a small-scale uncertainty in the parameters within each facies. We propose an approach that combines random domain decompositions (RDD) and polynomial chaos expansions (PCE) to account for the large- and small-scales of uncertainty, respectively. We present a general framework and use a one-dimensional flow example to demonstrate that our combined approach provides robust, non-perturbative approximations for the statistics of the system states.
Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 135
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Author: David Crevillén García
Publisher:
ISBN:
Category : Carbon sequestration
Languages : en
Pages : 0
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Author: Proper K. Torsu
Publisher:
ISBN: 9781369094176
Category : Multiphase flow
Languages : en
Pages : 88
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This dissertation investigates models of multiphase flow in porous media with the goal of understanding the behavior of classical and novel descriptions of flow, the strengths and shortcoming of each, and establishing numerical solutions for various models to demonstrate their accuracy. Of particular interest are equilibrium and non-equilibrium imbibition models. Our studies have revealed new findings and results which open new avenues of research and applications in the future. With respect to non-equilibrium models, the contributions of this work to existing results include extension of a spontaneous countercurrent imbibition model studied by Silin and Patzek to second order and its capability to accommodate non-constant redistribution time. The study has demonstrated that late time asymptotic solutions do not depend on relaxation time. Moreover, an analysis of the extended model has revealed that recovery scales with square root of time; an important results established by Barenblatt, Ryzhik and Sinlin and Patzek. Another important study in this direction is a decomposition method for solving quasilinear initial boundary value problems, especially transport systems. This study was inspired by Adomian decomposition, a technique for solving nonlinear partial differential equations. One primary limitation of the Adomian decomposition is its inability to solve boundary value problems with zero or constant boundary conditions in general. In this work, the traditional Adomian decomposition method has been extended to quasilinear initial boundary value problems. The method has been applied to several standard problems in engineering and physics. In a slightly different direction, this dissertation also explored several aspects of Uncertainty Quantification of parameters in reservoir engineering. We studied a decomposition method for quantifying uncertainty associated with coefficients reservoir in modeling. This method has been applied to optimization of well placement problems; where it is integrated into a simulator for the transport system. If applicable, the method in general serves as a replacement for Monte Carlo simulations. It has been demonstrated in this dissertation that the decomposition method is substantially more efficient in comparison to the traditional Monte Carlo simulations. It also offers a variety of choices between computational resources, time and accuracy of the approximations.
Author: Gedeon Dagan
Publisher: Cambridge University Press
ISBN: 9780521572576
Category : Science
Languages : en
Pages : 241
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Book Description
A valuable reference work for research workers and professionals in hydrology, environmental issues, petroleum and geological engineering, and applied mathematics.
Author: Philippe Renard
Publisher: Frontiers Media SA
ISBN: 2889636747
Category :
Languages : en
Pages : 177
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Book Description
Numerical models of flow and transport processes are heavily employed in the fields of surface, soil, and groundwater hydrology. They are used to interpret field observations, analyze complex and coupled processes, or to support decision making related to large societal issues such as the water-energy nexus or sustainable water management and food production. Parameter estimation and uncertainty quantification are two key features of modern science-based predictions. When applied to water resources, these tasks must cope with many degrees of freedom and large datasets. Both are challenging and require novel theoretical and computational approaches to handle complex models with large number of unknown parameters.
