Fertilizing grass for hay and pasture

19 Aug.,2024

 

Fertilizing grass for hay and pasture

N fertilizer response comparing urea N broadcast at 50 kg/ha (45 lb/ac) versus ammonium nitriate N broadcast at 50 kg/ha (45 lb/ac) on an irrigated Dark Brown soil at Lethbridge An important part of efficient cattle production is ensuring there is sufficient grass for both summer pasture and hay for winter feed.

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An important part of efficient cattle production is ensuring there is sufficient grass for both summer pasture and hay for winter feed. Most Prairie farmers do a very good job fertilizing their annual crops, but hay and tame pasture often do not receive the same high level of fertilizer management. Lower soil nutrient levels can often limit forage production and quality.

With about 20 million acres of Prairie land in tame hay or seeded pasture, the productivity of many hay and pasture fields can be improved with very good fertilizer management.

Generally, Brown and Dark Brown soils in the southern Prairies are often deficient in nitrogen (N) and in phosphorus (P), but usually are not deficient in potassium (K) or sulphur (S) for grass production. Black, Gray Wooded and Gray-Black transition soils are commonly deficient in N and P and are more frequently deficient in K and/or S, particularly on sandy soils.

Grass has a relatively high demand for nutrients to achieve good yield and quality. Generally, for each ton of dry matter harvested, about 25 to 30 lb/ac of N, 10 lb/ac of P2O5, 50 lb/ac of K2O and 5 lb/ac of S are taken up from the soil. Removal rates vary depending on grass species and growing conditions.

Nutrient status of soils

Nitrogen is often the most limiting nutrient in grass production. Most of the N stored in soil is contained in soil organic matter. Each year, only a small amount of N is released from organic matter through soil microbial breakdown, called mineralization. For optimum grass production, the amount of N required above that supplied from organic matter decomposition must be supplied by fertilization.

Optimum grass production requires adequate levels of soil P. The majority of prairie soils are naturally low in plant-available P. However, residual levels of P in soil will vary depending on past phosphate (P2O5) fertilizer use and livestock manure application. Fields that have received P2O5 fertilizer or manure application for a number of years may have good residual soil P levels and may not require additional P. Soil testing will help to determine this.

Grass also needs potassium, sulphur and micronutrients. Soil testing helps identify potential deficiencies.

Fertilizing established grass

Nitrogen: Nitrogen fertilizer requirements depend on the soil test level of nitrate-nitrogen (NO3-N) and the potential yield. The need for N increases as available soil nitrogen levels decline and available moisture increases. Generally, grass will draw down available soil N levels during the growing season, so often soil test levels of available N are frequently low at the end of the growing season. Grass will respond dramatically to N fertilizer when soil N is deficient and moisture conditions are good.

Table 1 provides general broadcast N fertilizer recommendations for various soil zones based on soil test N. Under very good moisture conditions, higher rates of N fertilizer are economical. However, high rates should only be applied when soil test NO3-N levels are low and moisture conditions are very good. Nitrogen fertilizer rates should be reduced when spring soil moisture conditions are drier than normal.

If possible, N fertilizer should be applied early in the spring, even before grass begins active growth. If more than one cut is planned, second cut nitrogen requirements should be applied immediately after the first cut is taken.

When only one cut is taken for hay, all N fertilizer should be applied in early spring. If two cuts are planned, then the total N to be applied should be split. Approximately 60 per cent of the N fertilizer could be applied in early spring, with the remaining N applied immediately after the first cut is completed.

When fertilizing grass for pasture, N applications could be split, using two to four split applications over the growing season, depending on production potential. For example, on irrigated pasture, about 200 lb N/ac is needed over the growing season. This total could be split into four applications: 60 lb N/ac in early spring, 50 lb N/ac in mid-June, 50 lb N/ac in mid-July and 40 lb N/ac mid-August. Various split application times and rates could be developed to suit the soil and climatic area, yield potential of the grass and the rotational grazing system used by the producer.

Ammonium nitrate (34-0-0) is an excellent N fertilizer for broadcast application but availability on the Prairies is extremely limited. Therefore, urea (46-0-0) is often the only single analysis granular N fertilizer commonly available for broadcast application. When broadcast applied, urea can be subject to significant volatilization when surface soil and air temperatures are greater than 5 C. Volatilization is the change from urea to gaseous ammonia that can result in N loss to the air. Producers can also use liquid N fertilizer (28-0-0; a 50:50 liquid blend of urea and ammonium nitrate). Liquid N can be successfully dribble-banded onto grass in spring, but urea in the liquid is subject to the same volatilization as granular urea.

Contact us to discuss your requirements of urea 46-0-0 nitrogen fertilizer. Our experienced sales team can help you identify the options that best suit your needs.

On Black and Gray soils, spring temperatures are generally cool enough to allow early spring broadcast urea with less N loss. However, on Brown and Dark Brown soils with warmer spring temperatures and windy Chinook conditions, urea volatilization can be a serious problem.

Urea fertilizer can be treated with a urease inhibitor that will reduce volatile losses of N for about 10 to 12 days.

Polymer-coated granular urea called ESN (45-0-0) is recommended by some agronomists for broadcast application to forages. However, Alberta research has shown that it generally does not release quickly enough in spring to meet N requirements in the early part of the growing season, and therefore its use is not recommended for broadcast application onto grass.

The amount of N fertilizer required for grass-alfalfa mixtures is less than for pure grass stands. As the percentage of alfalfa in the forage stand increases, the amount of N fertilizer applied should be reduced by approximately the same percentage. For example, if the recommended amount of N fertilizer for a pure grass stand is 60 lb/ac, then the recommended N in a stand with 25 per cent alfalfa would be reduced by about 25 per cent to 45 lb N/ac. There is little need for N fertilizer if the percentage of alfalfa exceeds the percentage of grass in a forage stand.

Phosphorus: Phosphorus fertilizer can be broadcast annually on grass stands in P-deficient soils. One strategy is to apply a batch application of P2O5/ac before grass establishment to meet crop requirements for four to six years. An application of 100 to 150 lb of P2O5 /ac is recommended on Brown, Dark Brown or Gray soils. In areas with higher production potential, such as Black soils or irrigated soils, 150 to 200 lb of P2O5 /ac application before establishment could be considered.

If P is limiting production, growers should apply an annual application of 20 to 40 lb of P2O5 /ac to meet crop removal rates, depending on yield potential. Under good moisture conditions, grass has feeder roots near the soil surface and can take up broadcast phosphorus with reasonable efficiency. Broadcasting is presently the only practical method of in-crop P2O5 fertilizer application and should be done in early spring. Dribble banding of liquid P2O5 (10-34-0) can also be used; however, the cost-per-pound of liquid P fertilizer is usually considerably higher than for granular P fertilizer. Table 2 provides general P2O5 fertilizer recommendations.

Potassium: Well-rooted grasses are fairly efficient in taking up soil K and do not commonly respond to K fertilizer. However, annual applications of potash fertilizer (K2O) should be considered (Table 3) in fields testing deficient in soil potassium. Applications should first be tried in carefully marked test strips to determine if K fertilizer is beneficial. On-farm strip trials are useful to check for a field-specific response to K fertilizer.

Sulphur: A soil test for plant-available sulphate-sulphur (SO4-S) can be useful to determine if S fertilizer is required. It is very important to note that plant available SO4-S can be highly variable across fields, particularly in fields with variable topography or soil textures. When a field is uniformly low in sulphur, a soil test is very useful to estimate S fertilizer needs. However, if only 10 to 20 per cent of a field is low in SO4-S, it can be difficult to identify these areas. Sulphate levels are usually adequate to high in the Brown and Dark Brown soil zones and frequently lower in the Black and Gray soil zones. Table 4 can be used as a general guide to determine when SO4-S fertilizer is required and how much to apply.

For more detailed information, consult your provincial Ministry of Agriculture website and a soil or forage crop specialist.

Nitrogen Math: Simple Calculations Give You the Right Rates

Being able to calculate how much fertilizer to put on to apply the right amount of nitrogen is important. (DTN/The Progressive Farmer file photo by Jim Patrico)

Fertilizer math is fairly straightforward, but since most growers (and even agronomists) only calculate it once or twice a year (fall and spring), it is easy to forget the routine.

That math can get more confusing this season as we put together the puzzle of buying the most cost-effective fertilizer, hitting yield goals while watching expenses, and taking into account the needs of modern hybrids and varieties.

I was reminded of how confusing that math can be in an from a reader who stated that he reads many articles about nitrogen use on corn and finds the messaging quite confusing: Farmers (and agronomists) use different terms in different regions, and compute corn's nitrogen needs quite differently depending on state recommendations and other factors. Even the way we track how many units of nitrogen are actually in a unit of fertilizer can be complicated, depending on whether the product used is a solid, liquid solution, or gas.

He wrote: "I typically put on 35 to 40 gallons of 32% split applied. One -- is this enough for 180 bu corn? Also is this 350/400 pounds of N as many articles (seem to) refer to or what is (the actual) pounds at this rate per acre. Or do I go back to units of N (per bushel). In which case at 180 bu, I would need 60 gallons of 32% for corn on corn?"

How much nitrogen to apply on corn? That is a complex question and there are many approaches. Gone is the day when we could use the old Iowa State approach of 1.2 pounds per bushel expected yield and take a credit for soybeans (1 pound per bushel soybean yield ) if in a corn/soybean rotation. That seemed to work when N was inexpensive, hybrids weren't efficient, most N was put on preplant (fall) and we didn't worry about losing nitrates into our watersheds and the Gulf of Mexico.

Today N is expensive, corn price is low, and we can't let N escape into the environment. Today's corn hybrids also are much more nitrogen efficient, and continuous corn is common. We see rates of 0.9 to 1.0 pound per bushel and some farmers are even pushing it to 0.7 to 0.8 pound per bushel yield goal. In general I believe the 1 pound per bushel expected yield works quite well, but we need to take the right credits and apply that N smartly to protect it from losses. As yields go up from 200 to 250 and now even 300 bushels per acre, it takes more N per acre and we have to be smarter on how we manage that investment.

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