Percolation Theory for Flow in Porous Media
Hunt, Allen.
Percolation Theory for Flow in Porous Media [electronic resource] / by Allen Hunt, Robert Ewing, Behzad Ghanbarian. - 3rd ed. 2014. - XXIV, 447 p. 188 illus., 18 illus. in color. online resource. - Lecture Notes in Physics, 880 0075-8450 ; . - Lecture Notes in Physics, 880 .
Percolation Theory: Topology and Structure -- Properties Relevant for Transport and Transport Applications -- Porous Media Primer for Physicists -- Fractal Models of Porous Media.-Specific Examples of Critical Path Analysis -- Hydraulic and Electrical Conductivity: Conductivity Exponents and Critical Path Analysis -- Other Transport Properties of Porous Media -- Pressure Saturation Curves and the Critical Volume Fraction for Percolation: Accessibility Function of Percolation Theory -- Applications of the Correlation Length: Scale Effects on Flow -- Applications of the Cluster Statistics -- Properties Based on Tortuosity -- Effects of Multi-Scale Heterogeneity -- Misconceptions.
This monograph presents, for the first time, a unified and comprehensive introduction to some of the basic transport properties of porous media, such as electrical and hydraulic conductivity, air permeability and diffusion. The approach is based on critical path analysis and the scaling of transport properties, which are individually described as functions of saturation. At the same time, the book supplies a tutorial on percolation theory for hydrologists, providing them with the tools for solving actual problems. In turn, a separate chapter serves to introduce physicists to some of the language and complications of groundwater hydrology necessary for successful modeling. The end-of-chapter problems often indicate open questions, which young researchers entering the field can readily start working on. This significantly revised and expanded third edition includes in particular two new chapters: one on advanced fractal-based models, and one devoted to the discussion of various open issues such as the role of diffusion vs. advection, preferential flow vs. critical path, universal vs. non-universal exponents for conduction, and last but not least, the overall influence of the experimental apparatus in data collection and theory validation. "The book is suitable for advanced graduate courses, with selected problems and questions appearing at the end of each chapter. [...] I think the book is an important work that will guide soil scientists, hydrologists, and physicists to gain a better qualitative and quantitative understanding of multitransport properties of soils." (Marcel G. Schaap, Soil Science Society of America Journal, May-June, 2006).
9783319037714
10.1007/978-3-319-03771-4 doi
Hydraulic engineering.
Statistical physics.
Hydrogeology.
Complex Systems.
Geoengineering, Foundations, Hydraulics.
Numerical and Computational Physics, Simulation.
Statistical Physics and Dynamical Systems.
GB1001-1199.8
551.4
Percolation Theory for Flow in Porous Media [electronic resource] / by Allen Hunt, Robert Ewing, Behzad Ghanbarian. - 3rd ed. 2014. - XXIV, 447 p. 188 illus., 18 illus. in color. online resource. - Lecture Notes in Physics, 880 0075-8450 ; . - Lecture Notes in Physics, 880 .
Percolation Theory: Topology and Structure -- Properties Relevant for Transport and Transport Applications -- Porous Media Primer for Physicists -- Fractal Models of Porous Media.-Specific Examples of Critical Path Analysis -- Hydraulic and Electrical Conductivity: Conductivity Exponents and Critical Path Analysis -- Other Transport Properties of Porous Media -- Pressure Saturation Curves and the Critical Volume Fraction for Percolation: Accessibility Function of Percolation Theory -- Applications of the Correlation Length: Scale Effects on Flow -- Applications of the Cluster Statistics -- Properties Based on Tortuosity -- Effects of Multi-Scale Heterogeneity -- Misconceptions.
This monograph presents, for the first time, a unified and comprehensive introduction to some of the basic transport properties of porous media, such as electrical and hydraulic conductivity, air permeability and diffusion. The approach is based on critical path analysis and the scaling of transport properties, which are individually described as functions of saturation. At the same time, the book supplies a tutorial on percolation theory for hydrologists, providing them with the tools for solving actual problems. In turn, a separate chapter serves to introduce physicists to some of the language and complications of groundwater hydrology necessary for successful modeling. The end-of-chapter problems often indicate open questions, which young researchers entering the field can readily start working on. This significantly revised and expanded third edition includes in particular two new chapters: one on advanced fractal-based models, and one devoted to the discussion of various open issues such as the role of diffusion vs. advection, preferential flow vs. critical path, universal vs. non-universal exponents for conduction, and last but not least, the overall influence of the experimental apparatus in data collection and theory validation. "The book is suitable for advanced graduate courses, with selected problems and questions appearing at the end of each chapter. [...] I think the book is an important work that will guide soil scientists, hydrologists, and physicists to gain a better qualitative and quantitative understanding of multitransport properties of soils." (Marcel G. Schaap, Soil Science Society of America Journal, May-June, 2006).
9783319037714
10.1007/978-3-319-03771-4 doi
Hydraulic engineering.
Statistical physics.
Hydrogeology.
Complex Systems.
Geoengineering, Foundations, Hydraulics.
Numerical and Computational Physics, Simulation.
Statistical Physics and Dynamical Systems.
GB1001-1199.8
551.4