Cecil Hammond, Retired Extension Engineer; Bill Segars, Extension Water Quality Specialist; & Charles Gould, Special Agent
Contents
- Factors Affecting Fertilizer Value & Recommendations for Application
- Determine How Much Manure Can Be Applied
- Solids in Liquid Manure
- Management Factors
Livestock and poultry manures contain nutrient
elements that can support crop production and
enhance the chemical and physical properties of soil.
Manure can be an asset to livestock and poultry
operations when its nutrients are used for fertilizer.
This publication provides information on (1) the
nutrient content of manures available for land
application, (2) how to determine manure application
rates and whether supplemental fertilizer will be
needed for maximum crop production and (3) how to
use management techniques to maximize the
fertilization potential of farm manures.
The type and amount of nutrients in livestock and
poultry manures and the nutrients' eventual
availability to plants may vary considerably. Some
factors affecting nutrient value of applied manure are:
type of ration fed; method of collection and storage;
amount of feed, bedding and/or water added; time and
method of application; soil characteristics; the crop to
which the manure is applied; and climate.
Increasing levels of various elements (copper,
arsenic, etc.) and inorganic salts (sodium, calcium,
potassium, magnesium, etc.) in feed will increase
their concentrations in manure. There is concern
about the potential toxic effects to plants of high
concentrations of heavy metals and salts in soil as a
result of high application rates of manure to the land.
Perform regular soil tests and manure analyses to
monitor the balance of nutrients in the soil on your
farm, especially on land receiving heavy manure
applications. From an environmental standpoint, limit
the rate of manure application to the needs of the crop
grown on the land.
Bedding and water dilute the nutrient
concentration of manure and reduce its value. On the
other hand, feed spilled and incorporated into the
manure increases the nutrient concentration.
Excessive feed spillage and/or inadequate agitation
may cause sludge buildup in liquid systems, making
removal of the manure more difficult.
The type of housing and/or waste handling system
you use greatly affects the nitrogen (N) concentration
of manures (Table 1). Major N losses occur when
manure is dried by sun and air movement or leached
by rain, as is the case in open lot systems. In contrast,
manure loses comparatively little N in a completely
covered facility using a manure pack or liquid pit
storage system. Loss of N is greatest in long-term
treatment or storage systems such as oxidation ditches
or lagoons.
| Table 1. Approximate Nitrogen Losses from Manure
as Affected by Handling & Storing |
| Handling Storing Methods |
Nitrogen Loss* |
| Solid Systems: |
| Manure Pack |
35% |
| Poultry Litter |
35% |
| Liquid Systems: |
| Anaerobic Pit |
25% |
| Oxidation Ditch |
60% |
| Lagoon |
80% |
| *Based on composition of manure applied to the land vs.
composition of freshly excreted manure. |
Phosphorus (P) and potassium (K) losses are
minimal (5 to 15 percent) for all but open lot and
lagoon manure handling systems. In an open lot, you
can lose from 40 to 50 percent of the manure's P and
K to runoff and leaching. However, most of the P and
K can be retained for fertilizer use by runoff control
systems (setting basins, detention ponds). In lagoon
systems, from 50 to 80 percent of the P in manure can
settle in the sludge layer and thus be unavailable if
only the liquid portion is applied to the land.
| Table 2. Approximate Nitrogen Losses from Manure
to the Air as Affected by Application Method |
|
Application
Method |
Type of Manure |
Nitrogen
Loss* |
| Broadcast
without cultivation |
Solid |
20% |
| Liquid |
25% |
| Broadcast with
cultivation** |
Solid |
5% |
| Liquid |
5% |
| Knifing |
Liquid |
5% |
| Irrigation |
Liquid |
30% |
| *Percent of total nitrogen in manure applied that was lost within
4 days after application. |
| **Cultivation immediately after application. |
You will realize maximum nutrient benefit from
manure if you incorporate it into the soil immediately
after land application (Table 2). Incorporation
minimizes N loss into the air and/or in runoff and also
allows soil microorganisms to start decomposing the
organic matter in the manure, thus making nutrients
available to the plant sooner. In addition,
incorporation of manures into the soil minimizes
odor.
Generally, P and K losses are negligible and are
not affected by the method of application; however,
incorporating manure minimizes P and K losses due
to surface runoff. Apply manure as uniformly as
possible to prevent local concentrations of
ammonium-N or other inorganic salts that can reduce
seed germination and crop yields.
By applying manure just before the planting date
of crops, you maximize plant nutrient availability,
especially in high rainfall areas and on porous soils
having rapid percolation. However, don't plant
immediately after heavy manure application. Salt
accumulation near the soil surface and/or a temporary
excess of ammonia resulting from the breakdown of
organic nitrogen lower germination and reduce
seedling growth. As an alternative, late fall
applications may be desirable because of labor
availability, field conditions, etc. Even though fall
applications may result in 5 to 10 percent total N loss,
the extra time allows soil microorganisms to more
fully decompose the manure and release its nutrients
for use during the following cropping season. This is
especially advantageous for solid manure which
contains much organic matter.
For sandy or coarse-textured soils, manures can
best be applied frequently and at low rates throughout
the growing season to provide environmental
protection and maximum plant growth. Soils with
more than 10 percent slope should not have manure
applied or if applied, use injection of liquid manure
into sod.
Not all manure nutrients are readily available to a
crop in the year of application. To be utilized by
plants, nutrients in manure must be released from the
organic matter in a water-soluble form. Manure
nitrogen is in ammonium (inorganic) and organic
forms. Potentially, plants could use all of the
ammonium-N in the year of application. Nitrogen in
the organic form, however, must be "released"
before plants can use it. In other words, the organic
nitrogen must be converted to ammonium (NH4)+ or
nitrate (NO3) -- before it can be utilized by plants.
Approximately 75 percent of the total N will be
available to crops during the year of application with
the remainder carried over and available the next
cropping season.
However, the rate of availability of N is largely
influenced by soil, climate, etc. In contrast, nearly all
the P and K in manures are available for plant use
during the year of application.
Table 3 shows the pounds of nutrients excreted
annually by various livestock per 1,000 pounds live-weight. The nutrient content of manure from your
farm might differ considerably from the values
presented here. These figures can, however, serve as a
guideline for planning purposes. Nutrient analysis of
the manure is highly desirable.
You can only determine the exact amount of
nutrients available for land application from your
operation by laboratory analysis. But you can use
Tables 1, 2, and 3 Calculate the approximate nutrient
value of your manure from Table 3, then subtract
storage and handling losses (Table 1) and application
losses (Table 2) to get the nutrients available at time
of application. With these figures you can estimate
the amount of manure to apply to a given crop area
and whether your crop will require additional
commercial fertilizer. In addition, if you know the
quantity of nutrients available from your operation per
year, you can determine how much land is needed for
manure disposal. Table 4 gives nutrient needs for
various crops. Apply to the land at such a rate that the
amount of available nutrients does not greatly exceed
the amount removed by the growing crop.
Example
A swine producer has a 1,000-head finishing
operation (averaging 125 pounds weight per animal)
in an enclosed confinement building. Liquid manure
is collected in a lagoon. If the manure is spread by
irrigation annually on land producing 150 bushels of
corn per acre, how many acres are required for
maximum fertilizer utilization?
Step 1. Determine the nutrient needs of the crop.
From Table 4, for 150 bushels of corn: N = 225
pounds/acre, P2 O5 = 80 pounds/acre, K2O = 215
pounds/acre.
Step 2. Determine the nutrient value of manure
from Table 3. Pounds nutrient/year/animal unit in
manure as excreted: N = 164, P2O5 = 124, K2O = 132.
Nitrogen value should be reduced 80 percent for
storage losses (Table 1) and 30 percent for application
loss (Table 2). This means only 23 pounds of N/1,000
pound animal unit are available for crop utilization.
At 125 pounds/head the number of 1,000 pound
animal units = 1,000 head x 125 pounds/head = 125 animal
units.
1,000 pounds/animal unit
To determine the total pounds of each nutrient
available, multiply unit values by the number of
animal units:
N= 23 x 125 = 2,875 pounds
P2O5 = 62 x 125 = 7,750 pounds*
K2O = 66 x 125 = 8,250 pounds*
*Assumes 50 percent recovery with little or no agitation of the
lagoon.
Step 3. Determine number of acres required for
maximum nutrient utilization. Divide total pounds of
each nutrient (from Step 2) by pounds of that nutrient
required per acre (from Step 1).
Acres Required for N = 2,875 ÷ 225 = 12.8
Acres Required for P2O5 = 7,750 ÷ 80 = 96.8
Acres Required for K2O = 8,250 ÷ 215 = 38.4
Thus P2O5 is the acreage-determining nutrient if
nutrients are fully utilized. Manure should be applied
over 96.8 acres to assure maximum utilization of the
manure (in actual practice, P and K are often over
applied to allow more nitrogen application). Make up
the remaining N and K2O required for production with
commercial fertilizer.
Step 4. Determine supplemental fertilizer needed
(total needs - supplied). Since manure will be applied
over 96.8 acres, the following total amounts of N,
P2O5, and K2O will be required:
N = 96.8 x 225 (from Table 4) = 21,780 pounds
P2O5 = 96.8 x 80 (from Table 4) = 7,744 pounds
K2O = 96.8 x 215 (from Table 4) = 20,812 pounds
Supplemental nutrient requirements may be
determined by subtracting nutrients available in
manure (from Step 2) from total nutrients required as
follows:
Supplemental N required = 21,780-2,875 = 18,905
Supplemental P2O5 required = 7,744-7,744 = 0
Supplemental K2O required = 20,812-8,250 =
12,562
Flushing gutters with recycled water from lagoons
can be a major obstacle when solids content is higher
than pumping equipment can handle. A major
handicap can occur when dairy freestall bedding, for
example, gets in the flush gutters and ultimately into
lagoons. Table 5 shows typical solids content of some
liquid waste handling systems.
| Table 5. Typical Solids Content of Some Liquid
Waste Handling Systems |
|
VS/TS* (%) |
Solid Content (%) |
| Manure Pit |
| Swine |
80 |
4-8 |
| Cattle |
82-85 |
10-15 |
| Poultry Layers |
69.8 |
25 |
| Holding Pond |
| Pit Overflow |
N/A |
1-3 |
| Feedlot Runoff |
N/A |
Less than 1 |
| Dairy Barn Wash
Water |
N/A |
Less than 1 |
| Lagoon |
| Single or First
Stage Swine |
N/A |
½ - 1 |
| (No bedding cattle) |
N/A |
1-2 |
| Second Stage |
N/A |
Less than ½ |
| *Volatile solids/total solids. Volatile solids will dissipate and
volatilize into the air over time. Values do not include any
bedding. |
Some additional management techniques which
will help insure safe and effective application of
manure to cropland follow:
- Incorporate manure into the soil immediately.
Otherwise, apply manure to surface at reasonable
distances from streams, ponds, open ditches,
neighboring residences and public buildings to
minimize runoff and odor problems.
- Minimize odor problems by using common
sense, especially during the summer. Spread
early in the day when the air is warming up and
rising rather than later when the air is cool and
settling, and do not spread on days when the
wind is blowing toward populated areas or when
the air is still. Good management helps avoid
neighbor complaints. Analysis from liquid
manure varies considerably depending on the
amount of dilution. Laboratory analysis is
recommended for all animal waste and soil
samples are recommended as well. Table 6
shows average nutrients in liquid manure.
- Apply manure to relatively level land -- if slope
exceeds 10 percent, knife liquid manure into sod.
- Agitate or mix liquid manure thoroughly in pits
to facilitate removal of settled solids and thus insure uniform application of the nutrients.
- Consider irrigating with dilute manures (lagoon
or runoff liquids) during dry weather to apply
needed water and nutrients to growing crops.
- Wash the plants with clean water to avoid leaf
burn when irrigating manure on growing crop.
- Avoid spreading liquid manure on water-saturated or frozen soils where runoff is apt to
occur.
- Apply sufficient water sometime during the year
to avoid accumulation of salts in the root zone of
soils in arid regions.
- Use good safety measures when moving manure
from tanks or pits. Because of oxygen deficiency
or toxic gas accumulation, avoid entering storage
structures when agitating the liquid manure.
The chemical and physical properties of soil, such
as water infiltration rate, water-holding capacity,
texture and total exchange (nutrient-holding) capacity
also affect how much manure can be safely applied to
land. Fine-textured soils have low water infiltration
rates; therefore, the rate at which liquid manure,
especially lagoon effluent, can be applied without
runoff may be restricted to the intake rate of the soil.
Coarse-textured soils, on the other hand, are quite
permeable and can accept higher rates of liquid
manure applications without runoff. But because most
coarse soils have a very low exchange (nutrient-holding) capacity, you may have to apply smaller
amounts of manure during the growing season to
minimize the chance of soluble nutrients entering
ground water. Organic matter in the manure is
decomposed more rapidly in coarse-textured than
fine-textured soil and during warm, moist conditions
rather than cold, dry conditions. However, fine-textured soils will retain the nutrients longer in the
upper profile, where plants can get them.
Published by the University of Georgia in cooperation
with the Tennessee Valley Authority in support of
AGRI-21 Farming Systems Demonstration Program.
TVA and Land Grant University cooperating.
The University of Georgia and Ft. Valley State College, the
U.S. Department of Agriculture and counties of the state
cooperating. The Cooperative Extension Service offers
educational programs, assistance and materials to all people
without regard to race, color, national origin, age, sex or
disability.
An Equal Opportunity Employer/Affirmative Action
Organization Committed to a Diverse Work Force
Circular 826 October 1994
Issued in furtherance of Cooperative Extension work, Acts
of May 8 and June 30, 1914, The University of Georgia
College of Agricultural and Environmental Sciences and
the U.S. Department of Agriculture cooperating.
Gale A. Buchanan, Dean & Director
last updated: 25 February 1997
http://www.bae.uga.edu/extension/pubs/c826-ed.html
[Publications][Bio & Ag Engineering]