The soil moisture velocity equation[1] describes the speed that water moves vertically through unsaturated soil under the combined actions of gravity and capillarity, a process known as infiltration. The equation is alternative form of the Richardson/Richards' equation.[2] [3] The key difference being that the dependent variable is the position of the wetting front
z
The soil moisture velocity equation[1] or SMVE is a Lagrangian reinterpretation of the Eulerian Richards' equation wherein the dependent variable is the position z of a wetting front of a particular moisture content
\theta
\left.
| dz | |
| dt |
\right\vert\theta=
| \partialK(\theta) | |
| \partial\theta |
\left[1-\left(
| \partial\psi(\theta) | |
| \partialz |
\right)\right]-D(\theta)
| \partial2\psi/\partialz2 | |
| \partial\psi/\partialz |
z
\theta
K(\theta)
\psi(\theta)
D(\theta)
K(\theta)\partial\psi/\partial\theta
t
The first term on the right-hand side of the SMVE is called the "advection-like" term, while the second term is called the "diffusion-like" term. The advection-like term of the Soil Moisture Velocity Equation is particularly useful for calculating the advance of wetting fronts for a liquid invading an unsaturated porous medium under the combined action of gravity and capillarity because it is convertible to an ordinary differential equation by neglecting the diffusion-like term.[5] and it avoids the problem of representative elementary volume by use of a fine water-content discretization and solution method.
This equation was converted into a set of three ordinary differential equations (ODEs)[5] using the method of lines[8] to convert the partial derivatives on the right-hand side of the equation into appropriate finite difference forms. These three ODEs represent the dynamics of infiltrating water, falling slugs, and capillary groundwater, respectively.
This derivation of the 1-D soil moisture velocity equation for calculating vertical flux
q
| \partial\theta | |
| \partialt |
+
| \partialq | |
| \partialz |
=0.
We next insert the unsaturated Buckingham–Darcy flux:[9]
| q=-K(\theta) | \partial\psi(\theta) |
| \partialz |
+K(\theta),
yielding Richards' equation in mixed form because it includes both the water content
\theta
\psi(\theta)
| \partial\theta | = | |
| \partialt |
| \partial | |
| \partialz |
\left[K(\theta)\left(
| \partial\psi(\theta) | |
| \partialz |
-1\right)\right]
Applying the chain rule of differentiation to the right-hand side of Richards' equation:
| \partial\theta | |
| \partialt |
=
| \partial | K(\theta(z,t)) | |
| \partialz |
| \partial | \psi(\theta(z,t))+K(\theta) | |
| \partialz |
| \partial2 | \psi(\theta(z,t))- | |
| \partialz2 |
| \partial | |
| \partialz |
K(\theta(z,t))
Assuming that the constitutive relations for unsaturated hydraulic conductivity and soil capillarity are solely functions of the water content,
K=K(\theta)
\psi=\psi(\theta)
| \partial\theta | |
| \partialt |
=K'(\theta)\psi'(\theta)\left(
| \partial\theta | |
| \partialz |
\right)2+K(\theta)\left[\psi''(\theta)\left(
| \partial\theta | |
| \partialz |
\right)2+\psi'(\theta)
| \partial2\theta | \right]-K'(\theta) | |
| \partialz2 |
| \partial\theta | |
| \partialz |
This equation implicitly defines a function
ZR(\theta,t)
{-\partial\theta}/{\partialz}
| \partialZR | |
| \partialt |
=-K'(\theta)\psi'(\theta)
| \partial\theta | -K(\theta)\psi''(\theta) | |
| \partialz |
| \partial\theta | -K(\theta)\psi'(\theta) | |
| \partialz |
| \partial2\theta/\partialz2 | |
| \partial\theta/\partialz |
+K'(\theta)
which can be written as:
| \partialZR | |
| \partialt |
=-K'(\theta)\left[
| \partial\psi(\theta) | |
| \partialz |
-1\right]-K(\theta)\left[\psi''(\theta)
| \partial\theta | +\psi'(\theta) | |
| \partialz |
| \partial2\theta/\partialz2 | |
| \partial\theta/\partialz |
\right]
Inserting the definition of the soil water diffusivity:
D(\theta)\equivK(\theta)
| \partial\psi | |
| \partial\theta |
into the previous equation produces:
| \partialZR | |
| \partialt |
=-K'(\theta)\left[
| \partial\psi(\theta) | |
| \partialz |
-1\right]-D(\theta)
| \partial2\psi/\partialz2 | |
| \partial\psi/\partialz |
If we consider the velocity of a particular water content
\theta
\left.
| dz | |
| dt |
\right\vert\theta=
| \partialK(\theta) | |
| \partial\theta |
\left[1-\left(
| \partial\psi(\theta) | |
| \partialz |
\right)\right]-D(\theta)
| \partial2\psi/\partialz2 | |
| \partial\psi/\partialz |
Written in moisture content form, 1-D Richards' equation is[10]
| \partial\theta | |
| \partialt |
=
| \partial | \left(D(\theta) | |
| \partialz |
| \partial\theta | \right)+ | |
| \partialz |
| \partialK(\theta) | |
| \partialz |
Note that with
\theta
D(\theta)
The primary assumptions used in the derivation of the Soil Moisture Velocity Equation are that
K=K(\theta)
\psi=\psi(\theta)
| \partialZR | |
| \partialt |
=-K'(\theta)\left[
| \partial\psi(\theta) | |
| \partialz |
-1\right]
where
{\partial\psi(\theta)}/{\partialz}
K'(\theta)
Neglecting gravity and the scalar wetting front capillarity, we can consider only the second term on the right-hand side of the SMVE. In this case the Soil Moisture Velocity Equation becomes:
| \partialZR | |
| \partialt |
=-D(\theta)
| \partial2\psi/\partialz2 | |
| \partial\psi/\partialz |
This term is strikingly similar to Fick's second law of diffusion. For this reason, this term is called the "diffusion-like" term of the SMVE.
This term represents the flux due to the shape of the wetting front
-D(\theta){\partial2\psi/\partialz2}
{\partial\psi/\partialz}
<\partial\psi/\partialz=C
\partial\psi/\partialz=-1
Another instance when the diffusion-like term will be nearly zero is in the case of sharp wetting fronts, where the denominator of the diffusion-like term
\partial\psi/\partialz\toinfty
Finally, in the case of dry soils,
K(\theta)
0
D(\theta)
Comparing against exact solutions of Richards' equation for infiltration into idealized soils developed by Ross & Parlange (1994)[12] revealed that indeed, neglecting the diffusion-like term resulted in accuracy >99% in calculated cumulative infiltration. This result indicates that the advection-like term of the SMVE, converted into an ordinary differential equation using the method of lines, is an accurate ODE solution of the infiltration problem. This is consistent with the result published by Ogden et al. who found errors in simulated cumulative infiltration of 0.3% using 263 cm of tropical rainfall over an 8-month simulation to drive infiltration simulations that compared the advection-like SMVE solution against the numerical solution of Richards' equation.
The advection-like term of the SMVE can be solved using the method of lines and a finite moisture content discretization. This solution of the SMVE advection-like term replaces the 1-D Richards' equation PDE with a set of three ordinary differential equations (ODEs). These three ODEs are:
With reference to Figure 1, water infiltrating the land surface can flow through the pore space between
\thetad
\thetai
| \partialK(\theta) | = | |
| \partial\theta |
| K(\thetad)-K(\thetai) | |
| \thetad-\thetai |
.
Given that any ponded depth of water on the land surface is
hp
| \partial\psi(\theta) | = | |
| \partialz |
| |\psi(\thetad)|+hp | |
| zj |
,
represents the capillary head gradient that is driving the flow in the
jth
| \left( | dz |
| dt |
\right)j=
| K(\thetad)-K(\thetai) | \left( | |
| \thetad-\thetai |
| |\psi(\thetad)|+hp | |
| zj |
+1\right).
After rainfall stops and all surface water infiltrates, water in bins that contains infiltration fronts detaches from the land surface. Assuming that the capillarity at leading and trailing edges of this 'falling slug' of water is balanced, then the water falls through the media at the incremental conductivity associated with the
jth \Delta\theta
| \left( | dz |
| dt |
\right)j=
| K(\thetaj)-K(\thetaj-1) | |
| \thetaj-\thetaj-1 |
This approach to solving the capillary-free solution is very similar to the kinematic wave approximation.
In this case, the flux of water to the
jth
| \partialK(\theta) | |
| \partial\theta |
=
| K(\thetaj)-K(\thetai) | |
| \thetaj-\thetai |
,
and
| \partial\psi(\theta) | |
| \partialz |
=
| |\psi(\thetaj)| | |
| Hj |
which yields:
| \left( | dH |
| dt |
\right)j=
| K(\thetaj)-K(\thetai) | \left( | |
| \thetaj-\thetai |
| |\psi(\thetaj)| | |
| Hj |
-1\right).
Note the "-1" in parentheses, representing the fact that gravity and capillarity are acting in opposite directions. The performance of this equation was verified,[7] using a column experiment fashioned after that by Childs and Poulovassilis (1962).[6] Results of that validation showed that the finite water-content vadose zone flux calculation method performed comparably to the numerical solution of Richards' equation. The photo shows apparatus. Data from this column experiment are available by clicking on this hot-linked DOI. These data are useful for evaluating models of near-surface water table dynamics.
It is noteworthy that the SMVE advection-like term solved using the finite moisture-content method completely avoids the need to estimate the specific yield. Calculating the specific yield as the water table nears the land surface is made cumbersome my non-linearities. However, the SMVE solved using a finite moisture-content discretization essentially does this automatically in the case of a dynamic near-surface water table.
The paper on the Soil Moisture Velocity Equation was highlighted by the editor in the issue of J. Adv. Modeling of Earth Systems when the paper was first published, and is in the public domain. The paper may be freely downloaded here by anyone.The paper describing the finite moisture-content solution of the advection-like term of the Soil Moisture Velocity Equation was selected to receive the 2015 Coolest Paper Award by the early career members of the International Association of Hydrogeologists.