Porous medium equation

Last updated November 17, 2023

The porous medium equation, also called the nonlinear heat equation, is a nonlinear partial differential equation taking the form:^[1]

Solutions

Despite being a nonlinear equation, the porous medium equation may be solved exactly using separation of variables or a similarity solution. However, the separation of variables solution is known to blow up to infinity at a finite time.^[2]

Barenblatt-Kompaneets-Zeldovich similarity solution

The similarity approach to solving the porous medium equation was taken by Barenblatt ^[3] and Kompaneets/Zeldovich,^[4] which for $x\in \mathbb {R} ^{n}$ was to find a solution satisfying:

u(t,x)={1 \over {t^{\alpha }}}v\left({x \over {t^{\beta }}}\right),\quad t>0

for some unknown function $v$ and unknown constants $\alpha ,\beta$ . The final solution to the porous medium equation under these scalings is:

u(t,x)={1 \over {t^{\alpha }}}\left(b-{m-1 \over {2m}}\beta {\|x\|^{2} \over {t^{2\beta }}}\right)_{+}^{1 \over {m-1}}

where $\|\cdot \|^{2}$ is the $\ell ^{2}$ -norm, $(\cdot )_{+}$ is the positive part, and the coefficients are given by:

\alpha ={n \over {n(m-1)+2}},\quad \beta ={1 \over {n(m-1)+2}}

Applications

The porous medium equation has been found to have a number of applications in gas flow, heat transfer, and groundwater flow.^[5]

Gas flow

The porous medium equation name originates from its use in describing the flow of an ideal gas in a homogeneous porous medium.^[6] We require three equations to completely specify the medium's density $\rho$ , flow velocity field ${\bf {v}}$ , and pressure $p$ : the continuity equation for conservation of mass; Darcy's law for flow in a porous medium; and the ideal gas equation of state. These equations are summarized below:

{\begin{aligned}\varepsilon {\partial \rho  \over {\partial t}}&=-\nabla \cdot (\rho {\bf {v}})&({\text{Conservation of mass}})\\{\bf {v}}&=-{k \over {\mu }}\nabla p&({\text{Darcy's law}})\\p&=p_{0}\rho ^{\gamma }&({\text{Equation of state}})\end{aligned}}

where $\varepsilon$ is the porosity, $k$ is the permeability of the medium, $\mu$ is the dynamic viscosity, and $\gamma$ is the polytropic exponent (equal to the heat capacity ratio for isentropic processes). Assuming constant porosity, permeability, and dynamic viscosity, the partial differential equation for the density is:

{\partial \rho  \over {\partial t}}=c\Delta \left(\rho ^{m}\right)

where $m=\gamma +1$ and $c=\gamma kp_{0}/(\gamma +1)\varepsilon \mu$ .

Heat transfer

Using Fourier's law of heat conduction, the general equation for temperature change in a medium through conduction is:

\rho c_{p}{\partial T \over {\partial t}}=\nabla \cdot (\kappa \nabla T)

where $\rho$ is the medium's density, $c_{p}$ is the heat capacity at constant pressure, and $\kappa$ is the thermal conductivity. If the thermal conductivity depends on temperature according to the power law:

\kappa =\alpha T^{n}

Then the heat transfer equation may be written as the porous medium equation:

{\partial T \over {\partial t}}=\lambda \Delta \left(T^{m}\right)

with $m=n+1$ and $\lambda =\alpha /\rho c_{p}m$ . The thermal conductivity of high-temperature plasmas seems to follow a power law.^[7]

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References

↑ Wathen, A; Qian, L. "Porous medium equation" (PDF). University of Oxford.
↑ Evans, Lawrence C. (2010). Partial Differential Equations. Graduate Studies in Mathematics. Vol. 19 (2nd ed.). American Mathematical Society. pp. 170–171. ISBN 9780821849743.
↑ Barenblatt, G.I. (1952). "On some unsteady fluid and gas motions in a porous medium". Prikladnaya Matematika i Mekhanika (in Russian). 10 (1): 67–78.
↑ Zeldovich, Y.B.; Kompaneets, A.S. (1950). "Towards a theory of heat conduction with thermal conductivity depending on the temperature". Collection of Papers Dedicated to 70th Anniversary of A. F. Ioffe. Izd. Akad. Nauk SSSR: 61–72.
↑ Boussinesq, J. (1904). "Recherches théoriques sur l'écoulement des nappes d'eau infiltrées dans le sol et sur le débit des sources". Journal de Mathématiques Pures et Appliquées. 10: 5–78.
↑ Muskat, M. (1937). The Flow of Homogeneous Fluids Through Porous Media. New York: McGraw-Hill. ISBN 9780934634168.
↑ Zeldovich, Y.B.; Raizer, Y.P. (1966). Physics of Shock Waves and High Temperature Hydrodynamic Phenomena (1st ed.). Academic Press. pp. 652–684. ISBN 9780127787015.

External links

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[1] Wathen, A; Qian, L. "Porous medium equation" (PDF). University of Oxford.

[2] Evans, Lawrence C. (2010). Partial Differential Equations. Graduate Studies in Mathematics. Vol. 19 (2nd ed.). American Mathematical Society. pp. 170–171. ISBN 9780821849743.

[3] Barenblatt, G.I. (1952). "On some unsteady fluid and gas motions in a porous medium". Prikladnaya Matematika i Mekhanika (in Russian). 10 (1): 67–78.

[4] Zeldovich, Y.B.; Kompaneets, A.S. (1950). "Towards a theory of heat conduction with thermal conductivity depending on the temperature". Collection of Papers Dedicated to 70th Anniversary of A. F. Ioffe. Izd. Akad. Nauk SSSR: 61–72.

[5] Boussinesq, J. (1904). "Recherches théoriques sur l'écoulement des nappes d'eau infiltrées dans le sol et sur le débit des sources". Journal de Mathématiques Pures et Appliquées. 10: 5–78.

[6] Muskat, M. (1937). The Flow of Homogeneous Fluids Through Porous Media. New York: McGraw-Hill. ISBN 9780934634168.

[7] Zeldovich, Y.B.; Raizer, Y.P. (1966). Physics of Shock Waves and High Temperature Hydrodynamic Phenomena (1st ed.). Academic Press. pp. 652–684. ISBN 9780127787015.

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