Green and Am-pt Infiltration:
The Horton
equation captures the basic behavior of infiltration but the physical
interpretation of the exponential constant is uncertain. Green and Ampt (1911)
presented an approach that is based on fundamental physics and also gives
results that match empirical observations. They use the following
simplification of infiltration reality
Infiltrating water wetting front; metric suction
pulls water into dry soil Dry soil saturated soil wetting front moves down into
dry soil HZf
In reality, there is often not a sharp wetting front and/or
the soil above the wetting front may not saturate. The equation to use if you
need to consider the most realistic situation is the Richard’s equation;
Richard’s equation is beyond the scope of this class but you should be aware of
it.
The problem with all mechanistic
infiltration equations is uncertainty about how to generalize to the field or
landscape scale, especially with respect to the suction forces at the wetting
front. None-the-less, many researchers are embracing these approaches and
making good progress so you should have some rudimentary knowledge of, at
least, the Green and Ampt concept.
Below is a summary of
the relevant Green and Ampt infiltration equations. We will revisit these later
in the semester after we are familiar with Darcy’s Law. The following equations
come from Mein R.G. and C.L. Larson (1973) [Modeling infiltration during a
steady rain. Water Resour. Res. 9(2): 384-394.] who reduced the Green
and Ampt concept to something applicable.
In its simplest form the Green and Ampt equation for
infiltration rate, f, can be written as:
The subscript “f” refers to the wetting front
and “o” refers to the soil surface, e.g.,
is
the hydraulic head at the wetting front (sum of matric forces at the wetting
front and the weight of the water above), and ho is the hydraulic head
at the surface (zero, unless there is water pounded on the surface).
f
=
matric pressure at the wetting front [cm of water], Ks = saturated
hydraulic conductivity [cm/hr]. The depth of the wetting front can be related
to the cumulative amount of infiltrated water, F [cm], by:
where
s = saturated
moisture content and i = initial moisture content before infiltration
began. Rearranging Eq. 2 to solve for Zf and substituting it into Eq.
1c, the infiltration rate, f(t), becomes:
where: P = rainfall rate [cm hr-1] and tp is
the time when water begins to pond on the surface [hr]. Unfortunately, Eq. 3a
does not have time as a variable but instead uses F, the cumulative
amount of water that has infiltrated. Recognizing that f =dF/dt,
we can solve Eq. 3 to get the following, somewhat complicated, expression for F(t):
where Fp = the amount of water that
infiltrates before water begins to pond at the surface [cm] and tp = the
time it takes to have water begin to pond at the surface [hr]. The following
are expressions of these quantities.
To determine the amount of infiltration from a rain
storm of duration, tr, and intensity P you will have to first
determine the time at which surface ponding occurs (Eqs. 4 & 5). If tr <
tp or P < Ks then the amount of infiltration, F =
Ptr and the infiltration rate, f = P. If td > tp,
then you will have to use Eq. 4 and find, by trial and error, the value F that
gives t = tr. I usually set up an Excel spreadsheet with a column
of F, incremented by small amounts, with adjacent columns for t (using
Eq. 4) and f (using Eq. 3). Then I can make graphs of infiltration rate
or amount verse time.
Example:
What’s the total runoff and infiltration [cm] from a
2-hour rainfall event with a 0.5 cm/hr intensity? When does runoff begin? The
soil’s Ks 0.044 cm/hr, i = 0.25 and s = 0.50, and f =
22.4 cm (we could calculate Ksand f if we know the soil type).
What’s the infiltration rate at the end of the storm? When you plot f vs
t, does the curve look like anything we’ve seen before?
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