An investigation of the mechanism of water removal from pulp slurries

Ingmanson, William L.

January 1951

Thesis (Ph. D.)--Institute of Paper Chemistry, 1951. / Includes bibliographical references (p. 117-119).

The compression creep properties of wet pulp mats

Wilder, Harry Douglas,

January 1960

Thesis (Ph. D.)--Institute of Paper Chemistry, 1960. / Includes bibliographical references (p. 164-165).

An investigation of the hot surface drying of glass fiber beds

Cowan, W. F.,

January 1961

Thesis (Ph. D.)--Institute of Paper Chemistry, 1961. / Includes bibliographical references (p. 161-162).

Catalysis of gas hydrates by biosurfactants in seawater-saturated sand/clay

Kothapalli, Chandrasekhar R.

January 2002

Thesis (M.S.) -- Mississippi State University. Department of Chemical Engineering. / Title from title screen. Includes bibliographical references.

Analysis of a Darcy-Stokes system modeling flow through vuggy porous media

Lehr, Heather Lyn

28 August 2008

Not available / text

Porous materials--Mathematical models

Fluid dynamics--Mathematical models

Darcy's law

Stokes equations

Simulating fluid flow in vuggy porous media

Brunson, Dana Sue

28 August 2008

Not available / text

Porous materials--Mathematical models

Fluid dynamics--Mathematical models

Finite element method

Cleanup of internal filter cake during flowback

Suri, Ajay

28 August 2008

Not available / text

Oil well drilling

Reservoir oil pressure

Permeability

Porous materials

Fluid dynamics

A volumetric sculpting based approach for modeling multi-scale domains

Karlapalem, Lalit Chandra Sekhar

28 August 2008

Not available / text

Computer simulation

Geometrical models

Iteratively coupled reservoir simulation for multiphase flow in porous media

Lu, Bo, 1979-

29 August 2008

Not available / text

Multiphase flow

Porous materials

Fluid dynamics

Secondary recovery of oil

Prediction of transient flow in random porous media by conditional moments

Tartakovsky, Daniel.

January 1996

This dissertation considers the effect of measuring randomly varying local hydraulic conductivity K(x) on one's ability to predict transient flow within bounded domains, driven by random sources, initial head distribution, and boundary functions. The first part of this work extends the steady state nonlocal formalism by Neuman and Orr [1992] in order to obtain the prediction of local hydraulic head h(x, t) and Darcy flux q(x, t) by means of their ensemble moments <h(x, t)> (c) and <q(x, t)>(c)conditioned on measurements of K(x). These predictors satisfy a deterministic flow equation which contains a nonlocal in space and time term called a "residual flux". As a result, <q(x, t)>(c) is nonlocal and non-Darcian so that an effective hydraulic conductivity K(c) does not generally exist. It is shown analytically that, with the exception of several specific cases, the well known requirement of "slow time-space variation" in uniform mean hydraulic gradient is essential for the existence of K(c). In a subsequent chapter, under this assumption, we develop analytical expressions for the effective hydraulic conductivity for flow in a three dimensional, mildly heterogeneous, statistically anisotropic porous medium of both infinite extent and in the presence of randomly prescribed Dirichlet and Neumann boundaries. Of a particular interest is the transient behavior of K(c) and its sensitivity to degree of statistical anisotropy and domain size. In a bounded domain, K(c) (t) decreases rapidly from the arithmetic mean K(A) at t = 0 toward the effective hydraulic conductivity corresponding to steady state flow, K(sr), K(c), exhibits similar behavior as a function of the dimensionless separation distance ρ between boundaries. At ρ = 0, K(c) = K(A) and rapidly decreases towards an asymptotic value obtained earlier for an infinite domain by G. Dagan. Our transient nonlocal formalism in the Laplace space allows us to analyze the impact of other than slow time-variations on the prediction of <q(x, t)>(c),. Analyzing several functional dependencies of mean hydraulic gradient, we find that this assumption is heavily dependent on the (relaxation) time-scale of the particular problem. Finally, we formally extend our results to strongly heterogeneous porous media by invoking the Landau-Lifshitz conjecture.

Hydrology.

Porous materials -- Fluid dynamics.