By Antonio P. Mallarino, Department of Agronomy
Questions often arise in June about "emergency or catch-up" fertilization for soybean. Most producers are not worried about this because they typically apply adequate amounts of phosphorus (P) and potassium (K) fertilizers before planting soybean or apply sufficiently large amounts before the previous year’s corn for both the corn and soybean crops. Producers asking questions wonder, however, if fertilizer rates were inadequate or if late planting dates, replanting and cold or excessively wet conditions have altered the crop nutrient uptake and fertilization need. Others wonder if the soil nutrient levels might limit high yield potential when growing conditions are good.
Is applying dry, granulated fertilizer a viable post-emerge option?
The short answer to this question is probably not. Typically this is not a good option for two main reasons. One, both P and K (but especially P) are needed at early growth stages to enhance plant cell multiplication when the number of nodes, leaves, and potential seed numbers are largely determined. Two, the application of fertilizer to the soil surface or banded/injected between the rows will be of low efficiency, mainly due to the common low or infrequent summer rainfall (perhaps not the case this year). There is only one situation in which an in-season application of granulated P and K fertilizer might be considered. That is when the soil tests are very low, and for certain the producer will have to apply a high fertilizer rate for next year’s corn crop to assure adequate P and K levels. Also, perhaps if the plan is to apply a greater than optimum rate to quickly buildup soil P and K test levels. In this scenario, an in-season application when the soybean plant is still small (only three or four leaves) may not be very efficient at increasing grain yield but will increase soil P and K levels and decrease the rate needed before the next corn crop.
What about foliar fertilization?
Some producers ask if foliar fertilization could help improve soybean growth and grain yield. It may, but the potential is quite low in fields that have been well fertilized or where growth is limited by factors other than nutrient supply.
Prior to the 1990s hundreds of field experiments conducted across de Midwest focused on foliar fertilization at late soybean reproductive stages (R4 to R7) using fertilizers that included nitrogen (N), P, K, sulfur (S), and other nutrients. Researchers theorized that if nutrients were applied to the foliage at this time, leaf senescence and “seed starving” could be alleviated and grain yields increased. A few early Iowa trials suggested that spraying a nutrient mixture in a ratio 10-2.3-3.6-0.5 N-P2O5-K2O-S between the R5 and R6 growth stages could increase yield by seven to eight bushels per acre. However, many subsequent trials in Iowa and across the Midwest and Southern states from the late 1970s to the early 2000s, showed inconsistent results, with an equal frequency of yield increases and decreases. More recent work in the Midwest under rain-fed conditions showed similar results, and often yield decreased when N sources were sprayed alone or in a mixture. The more positive results were observed under very high yield conditions with irrigation in Kansas. Therefore, these results have discouraged further research and adoption of foliar fertilization of soybean at late reproductive stages.
Other researchers thought that small amounts of nutrients sprayed onto soybean foliage at early growth stages could supplement inadequate pre-plant fertilization, increase nutrient supply even with presumably adequate pre-plant fertilization especially when soil conditions limit nutrient uptake. About 100 replicated field trials were conducted in Iowa from 1994 until the early 2000s to evaluate these possibilities. Applications included spraying foliar fertilizers with or without mixing with glyphosate herbicide at the V5 to R3 growth stages. The products tested (not all products were included in all trials) included the low-salt fluid fertilizer 3-18-18 (N-P2O5-K2O) and 10-10-10 (N-P2O5-K2O) both with or without S and with or without the micronutrients boron (B), iron (Fe), and zinc (Zn); and also 8-0-8 (N-P2O5-K2O). Product rates ranged from two to six gallons per acre applied once or twice (spaced 8 to 10 days). The fields were managed with no-till, ridge-till, or chisel-plow tillage. These results were summarized before and are only briefly, summarized here.
Results showed that foliar fertilization increased yield in 15 to 30 percent of fields depending on the trial set and year, and about 15 percent of fields on average. The average response to the best treatment across all fields was 0.7 bushels per acre. Differences between treatments were not consistent across fields, but responses tended to be higher for the three gallons acre rate of 3-18-18. Adding S or micronutrients did not produce higher yield, and the highest rate of 10-10-10 (with or without S) and 8-0-8 fertilizers reduced yield in a few fields (some leaf burn was observed). Yield with the double applications were the same as single applications.
As expected, yield increases were observed in fields testing low in P and K, but sometimes also in fields testing Optimum or higher due to reasons difficult to identify. Soil-test results, tissue-test results, and climatic conditions did not support strong conclusions, but suggested that conditions in which a response to foliar fertilization was more likely included ridge-till and no-till fields and slow early plant growth and P or K uptake due to cool early temperatures and excessive rainfall. Therefore, conditions that inhibit root growth and/or nutrient uptake early during the growing season (except drought) increased the likelihood of a yield response.
Five field trials conducted in 2005 and 2006 that studied foliar fertilization and fungicide application alone or in a spray mixture produced even more disappointing results for foliar fertilization (Figure 1). Eight treatments were a non-treated control, four foliar fertilization treatments without fungicide (a single application of three gallons per acre of 3-18-18 at the V5 and R2 to R3 growth stages, a double 3-18-18 application at V5 and R2 to R3 stages, and 3.3 gal/acre of 28 percent UAN at the R2 to R3 stages), and three fungicide (Headline®) treatments at the R2 to R3 growth stages (alone and in combination with 3-18-18 or UAN fertilizer). On average the fungicide increased yield by 2.9 bushels per acre, although the responses were statistically significant only at three fields. The fungicide delayed leaf senescence at most fields, although clear disease control was observed only for Brown Spot in three fields. Spraying soybean with 3-18-18 fertilizer did not affect yield at four fields and increased it slightly at one field. Spraying with UAN did not affect yield at two fields, increased it slightly at one field, and decreased it at two fields. The UAN application caused moderate leaf burning and the 3-18-18 application caused no burning. Mixing the two fertilizers used in this project with the fungicide did not cause problems or an additional yield response compared to the products alone.
In-season fertilizer application for soybean seldom will be cost-effective in Iowa production systems. The exception might be when soil samples confirm that the soil tests very low or low and there was insufficient preplant fertilization. A large application of granulated fertilizer to soil during the very early growth stages may result in some yield increase and will begin to build up soil test levels that will have to be increased for the next crop anyway, but the economic benefit for this year's soybean is very doubtful. The probability of an economic response to foliar fertilization is small, but this practice may be justified when nutrient deficiency symptoms are obvious, with confirmed deficient-testing soil, or when soil or climatic factors (other than drought) limit nutrient uptake in late spring and early summer.
Figure 1. Effects of foliar fertilization and fungicide application on grain yield of soybean (average across five trials in Iowa).
Antonio Mallarino is a professor of agronomy, with research and extension responsibilities in soil fertility and nutrient management. Mallarino can be reached at email@example.com or by calling (515) 294-6200.