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Urea-Based Fertilizers in Forage Production

Publication Number: P2678
View as PDF: P2678.pdf

Efficient forage production systems get the most value out of fertilization. This means taking steps to minimize nutrient losses. As fertilizer costs increase (Figure 1), it becomes even more important to make good decisions regarding fertilizer applications.

Line graph showing the increase in different fertilizer costs (UAN solution, urea, ammonium nitrate, DAP, and potash) from 2000 to 2010. DAP and potash experienced the greatest increases during 2008 and 2009, but all fertilizer prices increased during this time.
Figure 1. Average U.S. farm prices for selected fertilizers. Source: USDA, 2011.

Traditional fertilizer applications such as 13-13-14, 17-17-17, or DAP are not always recommended to optimize forage production. Rarely do forage crops need the primary nutrients (N, P, and K) on a 1:1:1 basis.

The best way to determine economically viable fertilizer requirements of forage crops is through soil testing. Following science-based fertility recommendations is cost-effective and will have greater benefits in the long term. It will help you avoid under- or overfertilization, which can reduce yields and profitability.

Because of increasing problems with storing and transporting ammonium nitrate, urea-based products such as urea (46-0-0), urea ammonium nitrate solutions (UAN) (28–32 percent), and urea ammonium sulfate (33-0-0-12S) are becoming more popular among forage producers.

It is important to understand how these urea-based products are broken down at the time of application. For urea to be used by forages, it has to be converted into ammonia (NH3) and then react with water in the soil to form ammonium (NH4+). This conversion process, called hydrolysis, is encouraged by urease, an enzyme found in soil.

Ammonia that does not react with water in the soil surface will likely escape into the atmosphere through a process called volatilization. During the conversion of urea to ammonia, soil pH around the applied urea granules can increase to nearly 9.0. This pH increase contributes to volatile gaseous losses of ammonia.

Estimates of ammonia volatilization from urea or urea-containing fertilizers vary widely due to the many conditions that influence volatile loss (Figure 2). Typical losses between 10 and 40 percent may be expected. Several environmental conditions affect the rate of ammonia volatilization. These include the amount of surface residue, soil water content, temperature, and soil pH.

Nitrogen cycle diagram described in caption.
Figure 2. The nitrogen cycle as it relates to urea and urea ammonium nitrate applications and their susceptibility to nitrogen loss mechanisms. Urea and urea ammonium nitrate are converted to ammonia by urease enzymes. Urea ammonium nitrate can also be converted to nitrate and ammonium. When surface applied, urea can volatilize, increasing nitrogen losses from 15 to 60 percent due to heat and humidity. Excessive rain, especially in sandy soils, could increase nitrate leaching away from the root zone, decreasing plant uptake. Nitrate and ammonium from urea ammonium nitrate can also volatize. Under less than ideal conditions, nitrate and ammonium can be broken down by microbial denitrification into nitrogen gas, causing volatilization of up to 5 percent, while nitrate can be subject to leaching. Source: Adapted from Nielsen, 2006.

Soils that have high organic matter content also tend to have higher urease concentrations. High concentrations of soil organic matter and crop residues increase urea hydrolysis rates and volatilization. This is largely because the urease enzyme is produced by microorganisms that are more active in the presence of organic material. As a result, forage systems may have higher surface urea hydrolysis rates than bare soil and conventional tillage systems.

Ammonia volatilization reduces the economic efficiency of fertilization in forage production systems, especially in hay. Either yield will be reduced or costs will increase because additional applications of nitrogen fertilizer are needed.

The time between urea application and precipitation is critical. When applying urea, it is important that it is washed into the soil either by rainfall or irrigation (more than 0.1 inch) within 2 to 3 days. Up to 30 percent of the available nitrogen can be lost through atmospheric volatilization within 72 hours of application. A urease inhibitor could act as an insurance policy in case rainfall does not come quickly enough.

Urea-based products are more efficient on cold, dry soils. For this reason, urea may be a good fertilizer choice for cool-season forage production in late fall, late winter, or early spring (March to mid-May) when soil temperatures are still below 65°F.

One of the most risky times to use urea-based products is in midsummer when air temperatures and humidity are very high. Urea volatilization increases when soil temperatures are above 65°F (Figure 3) and humidity is above 60 percent. Higher NH3 losses are expected when the relative humidity of the air is greater than the critical humidity of urea.

Bar graph shows that the percent of surface-applied urea volatilized over time increases as temperature increases (45 to 90 degrees F) and as time goes by (zero to 10 days).
Figure 3. Percent of surface-applied urea volatilized over time as ammonia at different temperatures. Urea was applied at a rate of 100 pounds of nitrogen per acre on a silt loam soil. Source: Overdahl et al., 1991.

The soil’s pH also has a strong effect on the amount of volatilization. Studies have shown that urea hydrolysis in high-pH soils (greater than 7.0) occurs within 2 days of application, while in acidic soils (low pH) the urea took twice as long to hydrolyze (Figure 4).

Bar graph shows that the percent of surface-applied urea volatilized over time increases as soil pH increases (5.0 to 7.5) and as time goes by (zero to 10 days).
Figure 4. Percent of surface-applied urea volatilized over time as ammonia at various soil pH levels. Urea was applied at a rate of 100 pounds of nitrogen per acre on a silt loam soil. Source: Overdahl et al., 1991.

When field conditions are not optimal, applying an N stabilizer or a urease inhibitor directly to the urea-based fertilizer could help reduce nitrogen loss. An N stabilizer is an additive that may be applied to dry or liquid urea-based fertilizers to create an active shield or coat that prevents catalytic reactions caused by urease. It allows plant uptake of stable forms of nitrogen for a longer period of time.

A urease inhibitor specifically blocks activity of the urease enzyme and slows hydrolysis to ammonia. Urease inhibitors prevent the urease enzyme from breaking down the urea for up to 14 days and decrease volatilization by up to 90 percent. This increases the chance that the urea nitrogen will be absorbed into the soil after a rain event rather than volatilizing into the atmosphere.

There is only one urease inhibitor on the market. Table 1 provides more detailed information about the composition, rate of application, and average retail price of commercially available urea fertilizer enhancers.

Table 1. Commercially available urea fertilizer enhancers.

Note: The mention of these products is for educational purposes only. Reference to commercial products or trade names does not imply discrimination or endorsement by the Mississippi State University Extension Service. These products have not been tested on forage production systems in Mississippi by the Mississippi State University Forage Extension Program, and use of these products by producers is at their own risk. Rate and prices are based on companies’ direct information and may vary by region or fertilizer dealer.

Product Name

Company

Fertilizer Application Rate – Dry (amount per ton of fertilizer)

Fertilizer Application Rate – Liquid (amount per ton of fertilizer)

Approximate Average Retail Price

Agrotain Ultra

Agrotain (NBPT urease inhibitor)

3.0 qt

1.5 qt

$72/gal

Environment Smart Nitrogen

Agrium

18–20 cents per lb per N unit

Nutrisphere-N

Special Fertilizer Products

2.0 qt

$125/gal

NZone

AgXplore

4.0 qt

2.0 qt; 18–24 oz for liquid manure

$50/gal

Upgrade

Atlantic-Pacific Ag

3.0 qt

$35/gal

N stabilizers may be more beneficial during the summer than early in the season. Early-season applications will reduce N availability and may prevent warm-season grasses from reaching maximum early growth after perennial grass species break dormancy. Pre-coated products such as ESN should be used in small ratios with uncoated urea early in the season to ensure that plants will have the necessary available nitrogen.

A study conducted at the University of Georgia on Russell bermudagrass indicated that Agrotain reduced ammonia volatilization by more than 63 percent and produced 11 percent more forage yield when compared to urea applied in the same way. There also was a 19 percent increase in recovery of applied nitrogen.

A study conducted in 2010 at Mississippi State University showed no advantage of Nutrisphere-N-coated urea products in annual ryegrass production. This is an indication that fertilizer enhancers will not give a yield advantage in the spring; they should be used mainly in the summer and early fall when temperature and humidity are high, and volatilization loss potential is lower.

When trying some of the available products, do so cautiously. Use them on a small area, and leave untreated check strips (uncoated urea application versus urea with enhancers) for comparison of results. Do not judge results solely on plant appearance, but also on forage yield and quality.

Fertilizer enhancers are intended to treat urea-based fertilizers (granular or liquid). They are not for use on the soil to impede the volatilization or loss of nitrogen in pasture or hay field situations where fertilizer will be broadcast. It is important to evaluate your hay production systems before deciding if fertilizer enhancers will fit into your management system. It is difficult to cut forage production costs without compromising yield, but investing in fertilizers in a more efficient way could help reduce fertilizer expenses.

Application of high N rates or the entire amount at the beginning of the season does not provide any economic advantage and could lead to unnecessary environmental risks such as leaching, volatilization, or nitrate toxicity. One approach to reducing nitrogen loss is splitting nitrogen applications throughout the growing season. Splitting nitrogen among two to four applications during the season could help increase yields by 5–10 percent and N use efficiency by 20–30 percent.

Another good approach is to apply nitrogen, phosphorus, and potassium to hay fields where soil pH is in the optimum range and there is an indication of an economic yield response. Always follow the four Rs of nutrient stewardship: use the right product, use the right rate, use it in the right place, and apply it at the right time.

References

Hancock, D. (2010). Nutrient management in pasture systems. Mississippi Forage and Grazing Land Conference.

Jones, C. A., Koenig, R. T., Ellsworth, J. W., Brown, B. D., & Jackson, G. D. (2007). Management of urea fertilizer to minimize volatilization. Montana State University Cooperative Extension Service Publication EB-173.

Mikkelsen, R. (2009). Ammonia emissions from agricultural operations: Fertilizer. Better Crops, 93(4), 9–11.

Nielsen, R. L. (2006). N loss mechanisms and nitrogen use efficiency. Purdue Nitrogen Management Workshop. Purdue University, West Lafayette, IN.

Olson-Rutz, K. (2009). Enhanced efficiency fertilizers. Montana State University Cooperative Extension Service Publication EB-0188.

Overdahl, C. J., Rehm, G. W., & Meredith, H. L. (1991). Fertilizer urea. University of Minnesota Cooperative Extension Service Publication WW-00636-GO.

The Nitrogen Cycle. (2005). In: J. L. Havlin, J. D. Beaton, S. L. Tisdale, & W. L. Nelson. Soil fertility and fertilizers: An introduction to nutrient management. Upper Saddle, NJ. Prentice Hall.

United States Department of Agriculture (USDA), Economic Research Service. (2011). Fertilizer use and price.


Publication 2678 (POD-10-24)

By Rocky Lemus, PhD, Extension/Research Professor, Plant and Soil Sciences.

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