Draining the Land Without
Polluting the Waters
ARS soil scientist Brandon
Grigg handles a water sample
from a Louisiana bayou to
measure fertilizer nutrients
transported from agricultural
production areas. Grigg's
research on soil drainage
represents just one part of
ARS' commitment to keeping
agricultural chemicals out
of the nation's waterways.
Deep in Mississippi Delta country, where Spanish moss grows on live
oaks and crawfish and alligators thrive, ARS
scientists are keeping their eyes on the ground. Specifically, they're
looking at how it drains. The results of their studies could affect
farming practices throughout the humid regions of the United States
and may also help reduce the size of the so-called dead zone in the
Gulf of Mexico.
This far-reaching experiment is an offshoot of a more region-specific
soil-drainage study that began 7 years ago.
Because field crops, like potted plants, languish when they're over-watered,
proper drainage is an important aspect of successful farming. Nearly
a third of the farmers in the Midwest rely on underground, or subsurface,
drainage to keep their plants healthy. Perforated pipes are placed at
a specified depth and grade below the surface of the soil. After a heavy
rain, excess water in the crop's root zone enters the pipe through the
perforations and flows away from the field to a ditch, stream, or other
outlet. The soil stays moist but doesn't get waterlogged, allowing plants
to grow faster and bigger.
Although the benefits of subsurface drainage have been well documented,
most farmers in the Lower Mississippi River Valley still rely on surface
drainage, which removes only standing water on top of the soil.
Agricultural engineer Jim
Fouss observes an algal bloom
on Alligator Bayou, near
Baton Rouge, Louisiana. These
blooms, a particular problem
during hot summer months,
can be caused by high
concentrations of fertilizer
nutrients from agricultural
Surprising Findings Below the Surface
A few years ago, scientists with ARS' Soil and Water Research Unit
(SWRU) in Baton Rouge, Louisiana, decided to compare the two drainage
approaches and determine which is the better management practice for
"We hypothesized that installing subsurface drainage on farms
in the Lower Mississippi River Valley would reduce pollution and improve
the productivity of the land," says agricultural engineer Jim Fouss,
SWRU's research leader. "The drains would act like sump pumps and
help get rainwater into the soil, reducing fertilizer and pesticide
runoff to ditches and streams."
Fouss and soil scientist Brandon Grigg tested this hypothesis by examining
data they collected from 16 research plots at Louisiana State University's
Ben Hur Research Farm over the course of 6 years, beginning in 1995.
They grew corn on the 0.2-hectare (about one-half acre) plots and followed
recommended tillage, fertilization, and pesticide application practices.
In 12 of the plots, they installed drainpipes 4 feet below the soil
surface, a common drainage depth. The other four plots remained drainpipe-free,
and all plots were graded to provide surface drainage.
What the scientists discovered surprised them. Underground drainage
did not significantly reduce the amount of water that ran off the surface
of the soil at any time during the study. During years with normal rainfall,
it did not significantly affect corn yield or the amount of soluble
nutrients lost from the field in surface runoff, either.
soils after harvest can
increase rainfall infiltration
and decrease surface runoff
and nutrient loss. Here,
Keith Whitehead, farm manager
at Louisiana State University's
Central Agricultural Experiment
Station, deep-chisels a field
in the high-rainfall region.
During drought conditions, howeverwhich existed in the test area
from 1998 through 2000underground drainage increased the total
amount of nitrate lost from the soil threefold. Much of this nitrate
loss took place late in the year, after the corn had been harvested.
The Soil Factor
The alluvial soil profile of the Mississippi Delta region is quite
different from soils typical of the humid Midwest. "In most areas,"
says Grigg, "porous soil forms the surface layer, and less permeable
soil lies underneath. But in the Lower Mississippi River Valley, the
top 8 inches of earth is very fine, made up of river sediment."
This fine soil sits on top and acts like a barrier, slowing down water
The barrier effect explains why subsurface drainage did not reduce
the amount of surface runoff and why Grigg's and Fouss's results were
the opposite of what they expected.
"An earlier study on subsurface drainage had been done in this
region," says Fouss. "The researcher found that the fields
with subsurface drainage had less surface runoff and nitrogen loss,
something our experiment didn't support. What we didn't take into accountand
what the other researcher hadn't emphasizedwas that he had deep-chiseled
the soil before planting."
At the Ben Hur Water Quality
Site at LSU Central
Agricultural Station in Baton
Rouge, Louisiana, Jim Fouss
and soil scientist Brandon
Grigg collect runoff water
samples for nutrient analysis
back at the laboratory.
To deep-chisel a field, a farmer attaches a short, angled shank to
a tractor tool-bar and pulls it down the rows, breaking up just the
top layer of soil. Deep-chiseling used to be a common practice in the
region, but farmers have moved away from it because they didn't see
any economic benefits and because minimum-tillage production has been
widely adopted during the past decade.
The absence of deep-chiseling may explain why subsurface drainage didn't
reduce surface runoff. But it doesn't account for why the plots with
subsurface drainage lost so much nitrate during the drought. Grigg explains
the phenomenon. "Between 1998 and 2000, the soil was so dry that
when it did occasionally rain, the water that didn't run off the surface
passed right through the dry and cracked soil, picking up soluble nitrate
and carrying it into the drainpipes." In these plots, nitrate was
washed out in concentrations of up to 200 parts per million10
times greater than the level expected.
Technician Katherine Davis
analyzes drainage water
samples for fertilizer-
nutrient content with an
Reducing the Dead Zone
Nitrate-nitrogen is a major contributor to the hypoxic zone in the
Gulf of Mexico. It is washed from fields to drainage ditches to streams,
which feed into rivers and, ultimately, the Gulf of Mexico. Just as
it helps crops grow on land, the nutrient also helps algae grow in water.
Unfortunately, when the algae start to die and decompose, the oxygen
in the water is depleted, creating an area that can't support most marine
When Fouss and Grigg looked at the data from their 1995-2001 study
and saw how much nitrate was being leached from the soil, they realized
just how important it is to manage drainage systems carefully. They
began designing a new experiment, focusing on how to reduce the amount
of nitrate lost through subsurface systems. The scope of their work
expanded from the Lower Mississippi River Valley to the entire humid
region of the United States.
Fouss and Grigg understood that although subsurface drainage may not
be necessary in the Lower Mississippi River Valley, it is an essential
tool for many farmers in other areas of the country. Without it, huge
tracts of farmland would have widely fluctuating water tables and would
not be nearly as productive. With their new study, they hope to collect
data that can be used to improve the design of future drainage systems
or retrofit existing ones, especially in the Midwest where much of the
Gulf of Mexico's nitrate-nitrogen problem originates.
Though improving drainage-water
quality is a primary goal, new
management practices must also
ensure profitable crop production.
Here, Brandon Grigg evaluates a
potential corn harvest.
They are including elements in their experiment proposed by Wayne Skaggs,
a distinguished professor at North Carolina State University and 2002
president of the American Society of Agricultural Engineers (ASAE).
During a presentation at the 1999 ASAE annual meeting, Skaggs proposed
that nitrogen losses from drained agricultural lands could be substantially
reduced by using shallow drains, narrowly spaced, instead of deeper,
more widely spaced drains.
He based this proposal on the results of a computer modeling study
in which drainage discharge and nitrate losses from drains at various
depths were simulated. In the model, shallower drainage raised the average
level of the water table, lowering soil nitrogen content by promoting
denitrification. This reduces the potential for nitrogen loss in drainage
"Agricultural profits are reduced somewhat with the shallow drains
because you have to put more pipe in," says Skaggs. But the cost
of removing nitrogen from drainage water may make the installation of
shallow drains the more profitable choice for farmers in the future.
This is an important consideration, since state and federal agencies
are increasingly regulating the total maximum daily load of nitrate
that farms may release into the environment.
Farmers must also consider the Farm Security and Rural Investment Act
of 2002. Once it is implemented, USDA will be able to provide cost sharing
to farmers who follow certain land-management practices that improve
water quality. Accordingly, the cost of installing environmentally friendly
drainage could be further reduced.
Currently, Skaggs is running two experiments with subsurface drainage
at depths ranging from 30 to 60 inches. In the coming year, Fouss and
Grigg will run an experiment with three types of drainage: surface drainage
only, shallow-installed drainage, and deep-installed drainage retrofitted
with water-control structures. This third type, called controlled drainage,
allows the grower to set the drainage outlet at any level between the
ground surface and the drainpipe. For example, with controlled drainage
set at 25 inches, the drainpipe could be 47 inches deep, but no water
would drain from it until the water table climbed to a depth shallower
than 25 inches.
Fouss and Grigg plan on deep-chiseling all three treatment sites so
their soils behave more like those in other humid agricultural regions.
They will also monitor a fourth treatment area that will have controlled
drainage but will not be deep-chiseled before planting. They will use
this as a control to further evaluate how deep-chisel plowing affects
surface runoff and nutrient movement in the Lower Mississippi River
Dale Bucks, head of ARS' national program for Water Quality and Water
Management, says that during this new experiment the scientists "should
expect to see a substantial reduction in nitrate losses from deep-chiseled
plots with controlled drainage. Skaggs and other researchers in North
Carolina and Ohio have shown a 30- to 40-percent reduction in nitrate
losses from subsurface drainage systems with controlled outlets. But
since controlled drainage isn't appropriate for many sloping or rolling
lands, it'll be interesting to see whether shallow drainage can match
these results in field trials."
The Sooner, the Better
Although this would be an important topic of study at any time, Fouss
and Grigg have an added incentive to test different drainage options.
Fouss explains: "Subsurface drainage is normally assumed to have
a life span of about 40 years, and much of what's currently in place
in the Midwest was installed in the 1950s and 1960s. Pretty soon, a
lot of farmers are going to need to replace what they have with something
that's both agriculturally and environmentally sound. This study and
others like it will help them decide what that approach should be."
During their research, Fouss and Grigg will cooperate with Skaggs,
as well as with researchers at ARS' Soil and Water Quality Research
Unit (SWQRU) in Ames, Iowa, and at the Soil Drainage Research Unit (SDRU)
in Columbus, Ohio. Skaggs is looking forward to the results. "We
have a great deal of information about how subsurface drainage affects
agricultural productivity," he says. "Now we need to consider
environmental factors. The more data we can gather, the better."
Norm Fausey, SDRU's research leader, agrees. Fausey is currently studying
how different levels of controlled drainage affect the amount of nutrients
lost from the soil. He says that the research Fouss and Grigg have planned
in Baton Rouge will be important to the entire humid region. "They're
doing direct comparisons of shallow and controlled drainage and their
effect on nutrient loss. We have very little data on this issue, and
it affects farmers all the way up the Mississippi and east to Maine
Like Fouss and Grigg, Dan Jaynes, SWQRU's research leader, is studying
ways to manipulate subsurface drainage to reduce nitrate losses. "Of
course," he says, "we will continue to study and advocate
specific management practices that reduce the amount of nitrate lost
from the soil, such as soybean/corn crop rotation and efficient fertilizer
application. But these practices alone will not solve the problem. Subsurface
drainage is the primary source of nitrate runoff in the Midwest. We
must find ways to either keep the nitrogen in the field or denitrify
the water before it drains into streams and rivers."
Bucks says, "One of our best chances for reducing nitrate pollution
in our streams, rivers, and the Gulf is by improving our surface and
subsurface drainage systems. We must invest in this research."
Current experiments will take at least 3 more years.By Amy
Spillman, Agricultural Research Service Information Staff.
This research is part of Water Quality and Management, an ARS National
Program (#201) described on the World Wide Web at http://www.nps.ars.usda.gov.
Jim Fouss and Brandon
Grigg are in the USDA-ARS Soil
and Water Research Unit, 4115 Gourrier Ave., Baton Rouge, LA 70808-4499;
phone (225) 578-0743 [Fouss], (225) 578-0746 [Grigg], fax (225) 757-7728.
"Draining the Land Without Polluting the Waters" was
published in the October
2002 issue of Agricultural Research magazine.