Summary: Soil applied fertilizer is intended for root absorption by plants. Manage fertilizer nitrogen (N) to keep as much of it as possible in the root zone to maximize crop N uptake, crop yield, and protect the environment. To keep urea fertilizer N in the root zone 1) incorporate urea into the soil with water or cultivation within a day or two of application and 2) don’t over irrigate when incorporating urea using water. Inject liquid fertilizers containing urea (for example, UAN32) into irrigation systems in the middle third of the irrigation set. This delivers urea N evenly through the root zone, avoiding leaching that can occur when urea is injected too early in the set and limited root zone distribution when injected too late in the set.
Background: Urea is the most commonly used dry nitrogen (N) fertilizer in the U.S. It provides half of the nitrogen in UAN (Urea Ammonium Nitrate) 28 or 32 liquid fertilizers. Dry and liquid fertilizers that contain urea have several advantages — relatively high N content (28-46% N), ease of handling and reasonable price relative to other N sources. However, nitrogen from applied urea can be lost from the root zone when used improperly, wasting money, reducing plant available N, and risking reduced crop growth and yield. The lost N can also be an environmental contaminant. Growers and PCAs should be aware of how to avoid N losses and get the most from urea fertilizer dollar.
Within days of application, urea N can be lost from the crop root zone in two ways – through ammonia volatilization or urea leaching. This article will briefly describe how these losses can occur and how to manage urea to avoid them.
The uncharged urea molecule (H2N-CO-NH2) breaks down in or on the soil into two ammonium molecules (NH4+) and a bicarbonate molecule (HCO3-) within days of application. Urease, a naturally occurring enzyme in soil and on plant surfaces, drives this reaction. Ammonium produced by urea breakdown (AKA urea hydrolysis) has many potential fates. It can shift form to ammonia (NH3; a gas), a process accelerated by high temperatures (over 70oF) and high pH. It can be held by the cation exchange capacity of clay or organic matter, absorbed by soil microorganisms or plants or changed into nitrate (NO3-) by certain soil bacteria (nitrification). Where urea transformation occurs has a major impact on whether the N applied actually enters and stays in the root zone.
Ammonia volatilization. Urea fertilizer – dry or liquid – applied to the soil surface and left there for days to weeks can lose >50% of N content into the air through ammonia volatilization. High soil pH, high soil temps (>70oF), sandy soils with low cation exchange capacity (CEC), weeds or turf, and moist soils/heavy dew all are factors that increase to ammonia losses from unincorporated urea. Incorporate urea into the soil within a day or two of application to avoid significant N loss.
Urea Leaching. Dissolved urea moves with water. Why? Urea hydrolysis takes several days to complete. Until hydrolysis occurs, the uncharged urea molecule won’t bind to soil particles. This helps with water incorporation, but can result in leaching of urea below the root zone during irrigation if excess water is applied. The most efficient use of urea fertilizer requires good irrigation management. Don’t over irrigate when incorporating surface applications or injecting urea-containing fertilizers through irrigation systems. When injecting urea fertilizer in a micro-irrigations system, a good rule of thumb is to add the fertilizer in the middle third of the irrigation set. For example, in a 12 hour irrigation set, add the urea in hours 4 to 8. This reduces the chances of pushing urea below the root zone or at least deeper in the root zone where there are fewer roots. Urea-containing fertilizer added late in the set is concentrated near the water source and not evenly distributed in the root zone.
Review. Surface-applied dry or liquid urea fertilizer must be incorporated as soon as possible or significant nitrogen losses will occur. Incorporation within 2 days of application is best. When irrigating to incorporate urea, don’t over irrigate. When injecting liquid urea fertilizer into irrigation system, apply fertilizer in the middle third of the irrigation set for the most even distribution in the root zone. How you use urea can go a long way to helping you get the most out of your fertilizer dollar.
*Valuable reviews and comments on this article were provided by Rob Mikkelsen, International Plant Nutrition Institute, and Sebastian Braum, Yara North America, Inc.
ajitpal
April 17, 2011David I am always impressed with your thought process and being in-line with what is needed. As a FYI, we were just having this discussion over the weekend regarding UREA and how to best manage it till possibly first week of June.
Thanks
ap
The Almond Doctor
April 18, 2011No problem Ajitpal. The true credit for last week’s article should go to Franz Niederholzer up in Yuba-Sutter. Fortunately, I am blessed to have colleagues who are interested in helping with the blog.
Matt
May 23, 2011David- Does this same research on Urea leaching apply to Can-17? Use the same rule of application during middle third of irrigation set?
Thanks for the almonddoctor.com!
The Almond Doctor
May 23, 2011Matt – short answer is yes, nitrate leaches, and it leaches easier than urea/ammonium. In regards to fertigation timing, that depends on the amount of water applied within your set. The goal is to apply the nitrogen so it does not move out of the rootzone. By estimating your water holding capacity (WHC) per foot of rooting depth, and applying less water than needed to fill the soil profile, the nitrate should stay within the rooting zone. For example, if on sand and assuming a WHC 0.6 in/ft, 4 foot rooting depth, applying nitrogen in an irrigation set that applies 1.5 inches is okay. Applying nitrogen in an irrigation that applies 3 inches will lose nitrogen to leaching.
Applying the nitrogen mid-irrigation set is recommended to ensure that the lines are charged before injection. Pushing product too soon can lead to an excessive dose being delivered to end trees, or leaching of the nitrogen. Pushing to late in the cycle will lead to more nitrogen remaining on the surface which is then lost to volatilization. This is why the middle third seems to be optimal timing.
Hope this helps.
Matt
May 25, 2011David-Good info. Couple questions- How do I find the WHC for my specific soil type (Dinuba Sandy Loam)? How deep are the most active feeder roots for almonds? Thanks again.
The Almond Doctor
May 26, 2011Matt,
Check out http://casoilresource.lawr.ucdavis.edu/drupal/node/902
It should have soil surveys that can be accessed directly, with your smart phone, google earth overlay, etc.
Once your orchard location is found, click the soil polygon to open up the information regarding the soil type. The number listed within the “Available Water Storage” is thw water holding capacity. Keep in mind that allowing the plant to use all of the water within the profile before triggering an irrigation is not a wise strategy. Check out a previous entry on irrigations and soils for a little more help: https://www.thealmonddoctor.com/2010/06/irrigation-scheduling-part-2_08.html
The Almond Doctor
May 26, 2011Forgot to answer the second question…usually we assume around three to four feet. Most likely there are roots deeper, but only if the soil profile is without stratification. Keep in mind that our most active root are is the top two feet due to the availability of oxygen, water, and nutrients applied through fertigation.