Nitrogen Management This Fall
URBANA, ILL
We are experiencing a
very early harvest in
Illinois. That reality
combined with fields that
were chopped, plowed under,
or harvested for biomass earlier
in the summer because
they did not produce grain is
resulting in many fields
cleared and ready for fall operations. Decisions
about applying nitrogen this fall rank high in
producers' priorities because the application
can affect profitability and the environment. As
I do every year, I'd like to review important
guidelines developed through years of research
and experience. I acknowledge that any given
recommended management practice may not
work very well every year, usually because of
environmental conditions beyond our control,
but I also emphasize that following these guidelines
will ensure the greatest chance to both
protect your N investment and enhance environmental
protection.
Nitrogen sources. For fall application, the only
recommended N sources are anhydrous ammonia
(NH3) and ammonium sulfate ([NH4]2SO4).
Ammonia transforms quickly to ammonium
(NH4+), and N in ammonium sulfate is already
in the ammonium form. Ammonium is adsorbed
onto the exchange sites in soil particles and organic
matter and thus is protected from leaching.
On the other hand, N sources containing
nitrate (NO3-) should not be used in the fall because
nitrate does not become adsorbed onto
exchange sites in the soil and can easily be
leached or denitrified long before corn plants are
ready to use it. Common fertilizers that contain
nitrate include ammonium nitrate (NH4NO3)
and urea ammonium nitrate (UAN).
Another common N source is urea (CO[NH2]2).
Urea converts to NH3 and then to NH4+ within
a few days of application. However, research has
demonstrated that this fertilizer should not be
used in the fall because it has a greater risk of
loss compared with anhydrous ammonia before
rapid nutrient uptake by the crop the following
spring. The same can be said of polymer-coated
ureas. While the polymer coating protects urea
for a while, often urea starts to diffuse out of the
granule too early, and the loss potential is
higher than for anhydrous ammonia. This is especially
true when the application is done too
early in the fall or in cases where inappropriate
handling of the fertilizer damaged the coating,
allowing for quicker dissolution of the urea
granule.
One of the benefits of anhydrous ammonia is
that it kills nitrifying bacteria (which are responsible
for the transformation of ammonium
to nitrate) at the point of application. In addition,
as ammonia reacts with water to form ammonium,
the reaction creates an alkaline (high
pH) environment within the ammonia retention
zone. This high pH also inhibits activity of nitrifying
bacteria for a while. However, these effects
are temporary.
To lengthen the period of bacterial inhibition,
it is a good idea to include a nitrification inhibitor
with the application of anhydrous ammonia.
Many years of research have indicated
that nitrification inhibitors, such as dicyandiamide
(DCD) and N-serve, can protect fall N
against loss and increase the amount of N present
in the ammonium form the following spring.
Just like with most practices, the use of a nitrification
inhibitor might not pay every year. For
example, if the following spring is dry and cool,
the inhibitor might not be as beneficial to enhancng
ammonium recovery. However, the
practice will overall ensure the greatest chance
to protect your N investment and at the same
time enhance environmental protection.
Ammonium sulfate is an excellent source for
no-till fields where broadcast applications are
preferred. It is always best to apply it before
soils freeze so the fertilizer can be dissolved and
be incorporated into the soil by rain. In fields
with minimal slope (less than 5 percent) and
where the potential for runoff is very low, it is
feasible to apply ammonium sulfate on frozen
ground because there is no concern of volatilization
loss. An important point to keep in mind is
that ammonium sulfate is more acidifying than
other N sources, so be sure to monitor soil pH.
As a general rule, 5 pounds of lime is needed to
neutralize 1 pound of N from ammonium sulfate,
compared with 2 pounds of lime per pound
of N from anhydrous ammonia.
Lastly, organic fertilizers derived from animals
(manure, poultry litter, etc.) are good fertilizer
sources that can be used in the fall. These products
supply N as well as phosphorus, potassium,
and other crop nutrients. Often these
organic fertilizers represent a less expensive
source of nutrients than inorganic fertilizers.
Timing N applications. In years like this, when
harvest is done so early, it is critical to keep in
mind that soil temperature can impact to a large
extent the efficiency of fall N applications and
the effectiveness of nitrification inhibitors. Nitrifying
bacteria are active till soils freeze (32°F),
but their activity is greatly reduced once soil
temperature goes below 50°F. For this reason, it
is recommended that the start of fall N applications
be directed by soil temperature and not by
calendar date, harvest date, or any other consideration.
The temperature guideline applies
equally for anhydrous ammonia, ammonium
sulfate, and manure/organic fertilizers that can
be used in the fall. Because the efficiency of nitrification
inhibitors also decreases with warm
temperatures, higher temperatures result in
faster breakdown of the molecule responsible
for inhibition of nitrifying bacteria. The cooler
the temperature, the greater the efficiency of the
inhibitor and the greater the chance that ammonium
does not convert to nitrate.
While I realize that anxiety levels rise every
year when soil temperatures are not getting
down to 50°F and falling steadily, I would also
like remind readers that in most years, the 50°F
temperature allows for N applications before
soils become too wet or frozen. There is no need
to increase the risk of N loss by starting applications
too early. Also, applying once temperatures
are 50°F does not ensure no loss of N, but
it does provide a better chance to protect your
investment.
Air temperatures in Illinois can vary substantially
in early fall. Even if they are getting to
50°F, historically the chance that temperatures
will continue to decline without a significant
bounce back up are very rare before the second
week of October in northern Illinois and the
third week in central Illinois. On average, soil
temperatures reach 50°F and continue to decrease
the first week of November in central and
northern Illinois. Daily maximum 4-inch baresoil
temperatures for Illinois this week have
been in the mid- to upper 60s.
Up-to-date soil temperatures can be accessed
at www.isws.illinois.edu/warm/soiltemp.asp.
However, these values should be used as a reference.
Since soil temperatures can be influenced
by multiple factors (including residue
cover, soil color, and drainage), it is always best
to monitor soil temperatures in individual fields
prior to N application.
Where can fall N be considered? Because temperatures
do not stay below 50°F long enough
during the winter, fall N application should not
be done south of a line roughly parallel to Illinois
Route 16. In areas near this boundary, soil
characteristics should be evaluated to determine
whether fall application is appropriate.
Soils with high potential for nitrate leaching in
the fall or early spring (sandy soils or those with
excessive drainage) should not receive fall N applications.
Also, regardless of location in the
state, soils with high potential for nitrate leaching
or that are very poorly drained should not
receive fall N applications.
Due to the length of time before use by the
crop, application of manure and other organic
N sources should be done as far as possible
from environmentally sensitive areas, such as
on steep slopes and near bodies of water. If the
application cannot be accomplished in late fall,
do not apply on frozen soils in the winter; it is
better to wait until spring.
How to apply N. When applying anhydrous
ammonia, make sure soil conditions are fit for
the application. Soils that are too dry or too wet
can result in ammonia losses to the atmosphere,
as the application knife tracks may not
seal properly. When soils are dry, increasing
depth of application or reducing application
rates typically can help minimize volatilization
losses. In wet soil conditions there is little that
can be done to minimize such losses. If you use
manure, poultry litter, or other animal-derived
fertilizer, incorporate it in the soil to avoid N
volatilization.
How much N? To determine the economically
optimal N rate at various corn and N prices, use
the Corn Nitrogen Rate Calculator. While the
calculator is designed to help you make the
most profitable decision for N management, it
does not account for carryover N that might
have been unused by crops because of the dry
conditions in many places this year. Also, if you
applied manure or the soil has high potential for
N mineralization (like in a field coming off of alfalfa),
you need to adjust the values from the
calculator to reflect what will be available next
year.
Once you determine how much N you will
need, remember that you need not make the entire
application in the fall. If a fall application
makes sense but you don’t like taking big risks,
consider applying some N in the fall and the rest
in spring. Many fields will likely have high nitrate
levels this fall because of the drought, and
it is uncertain how much of that N will be present
for the next crop. If a good portion is available,
that should be all the plant needs to get
started until sidedress time, which would reduce
the need to supply additional N in the fall.
If N is not present because of excessively wet
conditions in the spring, chances are that a fall
application of N could suffer similar losses.
Applying N in the spring, or splitting the application
to supply N closer to when plants will
need it, can increase use efficiency because
there is less chance for leaching or denitrification.
Research has also shown better efficiency
of nitrification inhibitors when smaller N rates
are used in the fall. So splitting the total application
might result in benefits on several fronts.
An ongoing study over three years showed
that fall applications reduced yield 17 percent
relative to preplant applications done within
three weeks of planting. The difference in yield,
averaged across N rates, was 23 bushels per
acre less with fall than with preplant applications.
We are conducting the study this year,
but I do not currently have yield information. I
suspect, though, that differences might not be
as large this year because there was very little N
loss potential in the spring and because the
drought was more limiting than any other factor.
Use caution. Be aware that anhydrous ammonia
is under a lot of pressure inside the nurse
tank, and when released it reacts quickly with
water. If ammonia comes in contact with skin,
eyes, or mucous membranes, it will cause dehydration
and burns, so please use extreme
caution when handling it. Δ