Thermodynamically constrained averaging theory provides a consistent method for upscaling conservation and thermodynamic equations for application in the study of porous medium systems. The method provides dynamic equations for phases, interfaces, and common curves that are closely based on insights from the entropy inequality. All larger scale variables in the equations are explicitly defined in terms of their microscale precursors, facilitating the determination of important parameters and macroscale state equations based on microscale experimental and computational analysis. The method requires that all assumptions that lead to a particular equation form be explicitly indicated, a restriction which is useful in ascertaining the range of applicability of a model as well as potential sources of error and opportunities to improve the analysis.
Author(s): William G. Gray, Cass T. Miller (auth.)
Series: Advances in Geophysical and Environmental Mechanics and Mathematics
Edition: 1
Publisher: Springer International Publishing
Year: 2014
Language: English
Pages: 582
Tags: Geophysics/Geodesy; Quantitative Geology; Mineralogy; Thermodynamics
Front Matter....Pages i-xxxiv
Elements of Thermodynamically Constrained Averaging Theory....Pages 1-36
Microscale Conservation Principles....Pages 37-85
Microscale Thermodynamics....Pages 87-134
Microscale Equilibrium Conditions....Pages 135-165
Microscale Closure for a Fluid Phase....Pages 167-199
Macroscale Conservation Principles....Pages 201-261
Macroscale Thermodynamics....Pages 263-300
Evolution Equations....Pages 301-326
Single-Fluid-Phase Flow....Pages 327-372
Single-Fluid-Phase Species Transport....Pages 373-420
Two-Phase Flow....Pages 421-463
Modeling Approach and Extensions....Pages 465-488
Back Matter....Pages 489-582
