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Managing Prevented-Planting Fields | an interview with Emerson Nafziger

by Emerson Nafziger, Extension Agronomist - University of Illinois
link to The Bulletin post

With a lot of acres of corn and soybeans still unplanted as we move into the second half of June, prevented planting (PP) is unfortunately going to be a major part of the story of the 2019 cropping season in Illinois. Here we’ll look at goals and options for managing acres on which the intended crop—corn or soybean—does not get planted.

Emerson Nafziger, University of Illinois Extension Agronomist, on how to manage Prevented Planting acreage this summer.

The main goals of managing PP acres will be: 1) providing a vegetative cover in order to keep the soil in place and to prevent “fallow syndrome”; 2) to prevent or manage weeds so they don’t reseed the field; and 3) to take up nitrogen, including that from any N-containing fertilizer (including DAP/MAP), and any N that will be released from soil organic matter during the growing season. We also need to find ways to keep costs down, given that the PP insurance payments leave little room for adding expenses to these acres. This may not be the best time to invest in expensive cover crop seeding mixes. With high demand this year, such seed—and seed of some less exotic cover crops as well—will be expensive, and some may not be available.

We have not seen “fallow syndrome” very often in Illinois, but there was some in 1994 in fields that were flooded for most of the season in 1993 and did not produce crops or even weeds that year. The symptoms include stunting and purpling that indicate phosphorus deficiency. Plants growing in fields host a type of beneficial fungus (VA mycorrhiza) that assists in the uptake of P; these fungi seem to die off when there aren’t any plants, and they come back slowly the next year. We don’t expect to see this in every field, and it’s more likely to show up where water stood for a long period of time this year. The best prevention is to have plants present sometime during this season to help maintain these fungi. Just about any plant with roots will work, including weeds, but a cover crop species we choose to plant will be preferable to weeds.

Having plants present to take up N is more to keep the N from leaving the field this year than it is to make it available for next year’s crop; it’s not clear how much N captured in crop biomass this season will become available to next year’s crop. But mineralization takes place in every field once soils are aerated, regardless of whether the previous crop was corn or soybean. Grasses with deep roots are the best way extract N from deeper in the soil, and to keep this N out of tile drainage water.

We won’t try to reiterate here the complex rules regarding PP certification, but will only deal with managing these fields to provide cover. It appears that any species will work as cover, as long as the rules regarding what’s done with the cover after the season are followed. That means no harvest of grain (or silage) at all, and harvest by grazing or by making hay only after November 1. Every decision on what to plant should be tested with your crop insurance agent beforehand.

PP corn

Where corn was the intended crop in 2019 and soybean is planned for 2020, using a small grain as a cover crop this summer is an option. Winterhardy cereal rye and wheat won’t form heads until after a period of temperatures in the 30s, so probably not until next spring. They should emerge and provide quick cover, but these are cool-season crops, and when they remain low-growing and don’t send up stems with heads, they likely won’t stay very healthy or grow vigorously through a normal summer season.

Spring oats or spring wheat might do a little better than winterhardy wheat or rye. These tend not to tiller much at high temperature, but they will set seed. It can’t be harvested as grain; check the rules on whether it can simply be left to have the seed shatter out in the fall once it’s ripe. That may reseed the cover crop, but these plants won’t survive the winter. None of these are likely to grow roots as deep as when they grow in cool weather, but they should provide decent cover. With the 2019 oats crop in Illinois planted late and not exactly thriving, it will be difficult to find seed locally. Spring wheat seed will have to come from states north and west of Illinois.

Grain from a bin or an elevator, including from this year’s harvest, might work as seed for small grains, since this is not a “crop” in the usual sense. With wet weather this spring, we anticipate that some harvested grain will have diseased kernels that lower its market price, which may provide an incentive for using it as cover crop seed. Test germination, and if germination is low, increase the seeding rate to plant about at least 15 viable seeds per square foot, using a drill. While drilling will usually produce better stands and require less seed, broadcasting 20–25 live seeds per square foot might work. Shallow tillage with a vertical-tillage implement before or after broadcast seeding will probably improve stands.

Sorghum-sudangrass hybrids and forage sorghum produce a lot of residue and are good at taking up soil N. These species grow well in high temperatures, and they tolerate dry soils. If they won’t be grazed (after November 1), it’s probably better to limit their growth to lower the amount of residue present next spring. Lack of adequate N will limit growth in most fields, and delaying planting until mid-July or so can also help. If there is still a lot of growth, plants can be mowed in September so the residue can start to break down this fall. Some sorghum-sudangrass hybrids are male-sterile, and these species don’t produce much seed in any case. There is no danger of having plants of these species overwinter.

In fields that haven’t had herbicides applied that would prevent their growth, species such as radish, turnip, rapeseed, buckwheat, and forage grasses and legumes could be used on PP corn acres. None of these will be as effective as a well-rooted grass crop at taking up N, and those that grow slowly after emergence will generally not provide good cover early, and they won’t compete with weeds very well. Their seed tends to be expensive, and those with very small seed (such as clovers) can be difficult to establish in mid-summer without specialized equipment.

It may be possible to plant corn on PP corn acres, as long as care is taken not to produce corn grain. Ways to assure this include planting it later than July 15, drilling or planting it in rows no more than 15 inches apart, and planting at least 70,000–80,000 seeds (roughly a bushel) per acre. Lack of N will also help keep seeds from forming or filling, as will very late (September) pollination, which should mean failure of the crop to mature. Some seed companies may offer treated seed that they won’t be keeping over at a price low enough to make this an option. It may also be possible to take seed out of a bin of non-GMO corn grain to use for this. Make sure such seed will germinate, and check to make sure the planter is dropping enough seeds. By the time frost kills them, corn plants should not have formed seed that is mature enough to germinate the next spring. If grain begins to form and seeds begin to fill despite these measures, the corn can be mowed with a stalk chopper to prevent formation of viable seeds.

Soybean PP

Management of PP soybean acres has the same goals as those for PP corn acres, but management changes some if these fields will go back to corn again in 2020. Undisturbed corn stalks have by now broken down to some extent, but they still provide some cover, and keeping some of the stalk material on the soil surface will help preserve moisture and to keep soil in place as a cover crop gets started. The presence of high-C residue from the previous corn crop means that there will be less net mineralization in these acres because some mineralized N will be tied up as microbes break down residues. Even so, good root growth from a cover crop will help to take up N and to keep it from leaving the field.

It is possible to use the growing season that remains in 2019 to produce a leguminous crop that can fix N to supplement the N supply for next year’s corn crop. Such a crop should provide good early growth in order to take up N present as the over crop is getting established. Clovers are small-seeded forage legumes that can work, although seed costs might be high and these species may be incompatible with any herbicides that were applied before planting was prevented. Planting them into corn residue will also be challenging, although no-till drilling may work if seed can be placed well. Broadcasting into corn stalks without tillage is not likely to result in good stands. Red clover is more widely available than more exotic clovers, but supplies of all of these might be limited this year. Sweet clover has larger seed and will grow aggressively once it’s established. It will usually provide more dry matter by spring, and will also be more difficult to control before planting the next crop, compared to other clovers. Hairy vetch also grows vigorously, but its seed is expensive and it may not overwinter very well; this species will work in southern Illinois but is probably not a good choice in central and northern Illinois.

Another legume that can provide fairly rapid cover and that is widely available is soybean. As with corn used as a cover crop, soybean should be planted late, in narrow rows and at a high seeding rate (80 to 90 lb of seed per acre, if germination is at least 80%), to provide fast cover and to keep seed production to a minimum. It is not clear that GMO soybean seed can be used to plant for any purpose except commercial grain production. In cases where treated soybean seed cannot be returned to the dealer, the seed company might be asked if use as cover crop seed this year is allowable. There is no other good use for this seed, and it will probably not remain viable if stored until next year.

Using bin-run non-GMO soybeans as cover crop seed for this should be possible; check with your seed dealer to make sure. Non-GMO soybeans are typically marketed as such, and so are likely to be limited in supply now, unless producers have them in their own bin. Later-maturing varieties would make more vegetative growth and be less likely to set and fill viable seeds than normal-maturing ones, but that would add the expense of finding and transporting such seed. All told, soybeans may not be as obvious a choice as they appear to be at first glance, especially if leftover seed can’t be used for this purpose.

Soybeans used as cover should not be allowed to set and fill viable seed. That’s both to avoid complications from planting a crop following prevented planting of the same crop, and also because the maturing crop may have more residue than desired. Mowing plants off at about stage R5 (beginning seedfill) should work to control growth and prevent seed formation while still allowing capture of some fixed N. A crimper-roller might also work. Soybean plants this size can be difficult to control with herbicides, and mechanical control that leaves the residue on or near the soil surface is probably a better option.

A small grain such as wheat or oats can also be used as a cover for PP soybean acres, although that means foregoing the fixation of nitrogen. These will probably be quite N-deficient when planted into corn stalks, and while this will limit the amount of cover they produce, they should make enough growth to provide fair cover by late fall. If winter wheat or rye is used, they should be terminated in the early spring so they don’t interfere with early growth of the corn crop that follows.

If P and K fertilizers were applied in preparation for this year’s crop that didn’t get planted, their availability for next year’s crop should not be affected as long as the soil stays in place. If MAP or DAP will be applied this fall, a green cover crop present at the time of application should take up some of the N in these P-fertilizer materials, and to preserve it from loss if application is made while soils are still warm. If P and K couldn’t be applied for this year’s crop, PP provides an opportunity to sample soils if needed, and to get these nutrients applied this fall. Late planting will mean late harvest of corn and soybeans this year, which will allow for timely fall work on PP acres.

Corn Acreage and Stocks | an interview with Todd Hubbs

by Todd Hubbs, University of Illinois
link to farmdocDaily post

Corn futures prices rallied about $0.90 per bushel since the beginning of May. The rally reflects expectations that planted acreage will fall well short of March intentions and on yield concerns associated with wide-ranging late planting. Demand weakness continues to emerge in the export market, but supply issues look to overwhelm any decrease in demand. The release of USDA’s Grain Stocks and Acreage reports on June 28 looks to set the tone for summer corn prices.

The end of the month USDA Grain Stocks and Acreage reports are less than two weeks away. Todd Gleason talks with University of Illinois ag economist and commodity marketing specialist about the projected numbers and how farmers should set this self up for marketing this year’s corn and soybean crops.

The reduction in corn planted acreage by three million acres and corn yield by 10 bushels per acre in the June WASDE appears to be a harbinger of things to come this year. The June estimate of planted acreage of corn is generally expected to be far less than intentions of 92.8 million acres reported in March. The only question remaining is the scale of acreage loss. The magnitude of prevented planting acres this year looks to eclipse the previous record of 3.6 million acres in 2013 by a wide margin. As of June 9, 14.5 million acres remained unplanted in the 18 states reported in the Crop Progress report. The amount of prevented planted acreage in those estimates remains uncertain, but the prospect of planting more than 14 million acres of corn after June 10 seems daunting.

Additionally, some acreage may have been switched to soybeans due to delayed corn planting over large areas of the Corn Belt. Recent wet weather brings soybean acreage planting into question as well. However, the prospect of a new round of Market Facilitation Payments provides a strong incentive to plant soybeans in the second half of June if weather permits. The June acreage estimate will probably not be changed until FSA certified acreage data becomes available in October. The final acreage estimate released in January tends to be less than the June estimate. Since 1996, the final estimate averaged 626 thousand acres less than the June acreage report in years when prevented planting acreage exceeded one million acres. This year may see a substantial drop from the June acreage estimate due to the uncertainty about planting during the survey period.

While the supply situation looks increasingly supportive of corn prices, current levels of corn use show weakness; particularly in the export market. The estimate of June 1corn stocks will reflect the recent decrease in consumption and reveal the pace of feed and residual use during the third quarter of the marketing year. The expected size of June 1 stocks can be calculated based on consumption data that are currently available and on the assumption that feed and residual use is on pace with the USDA projection of 5.3 billion bushels for the year. Based on the USDA’s Grain Crushings and Co-Products Production reports for March and April and on the EIA weekly estimates of ethanol production during May, corn used for ethanol production during the third quarter of the marketing year is estimated at 1.347 billion bushels. Corn used for other domestic industrial products is estimated at 362 million bushels.

Cumulative export inspections during the first three quarters of the marketing year totaled 1.549 billion bushels. Through April, Census export estimates exceeded export inspections by 149 million bushels. If that margin continued through May, exports during the first three quarters of the year totaled 1.698 billion bushels and indicated exports during the third quarter at 566 million bushels.

For the marketing year, the USDA projects feed and residual use of corn at 5.3 billion bushels. Feed and residual use during the first half of the year totaled 3.487 billion bushels. Use during the last half of the year needs to equal 1.813 billion bushels for total use to reach the USDA projection. Third and fourth quarter feed and residual use vary substantially over time. Feed and residual use near 954 million bushels during the third quarter this year sits close to the center of the range based on the historical data. With March 1 stocks of 8.605 billion bushels and imports during the quarter of 8 million bushels, the estimates of consumption during the quarter point to June 1 stocks of 5.384 billion bushels, 79 million larger than stocks of a year ago. A deviation from June 1 stocks less than 100 million bushels from the current estimate will not engender much price movement. The Acreage report on June 28 should overwhelm any information in the stocks report.

Uncertainty about corn acreage looks to remain in place through the summer. Weakening demand should not be a hindrance to a continued price rally since the supply situation is quite dismal. Strengthening corn basis and futures prices point to marketing strategies involving delayed pricing of the new crop. Price objectives need to be set to take advantage of current corn market dynamics. Managing crop price risk can be accomplished with a variety of marketing strategies. It is essential to have a marketing strategy since supply shocks provide a limited time frame to take advantage of pricing opportunities. The strategy probably should include plans for pricing some of the 2020 crop.

Corn Yield Implications of Late Planting

University of Illinois Extension Agronomist Emerson Nafziger discusses the impact of late corn planting and how farmers should set about nitrogen applications this spring. He was interviewed May 1, 2019 by Todd Gleason.

The following summary is taken from a May 1, 2019 University of Illinois farmdocDaily article written by agricultural economists Scott Irwin and Todd Hubbs.

“The impact of late planting on projections of the U.S. average corn yield is an important question right now due to the very wet conditions so far this spring through much of the Corn Belt. We estimate that the relationship of late planting with corn yield trend deviations is highly non-linear, with a largely flat segment up to 10 percent above average late planting and then a steeply sloped segment for late planting that is 10 percent or more above average. This nicely matches the curvature of planting date effects on corn yield estimated in agronomic field trials (e.g., farmdoc daily, May 20, 2015; Nafziger, 2017). The key then for 2019 is whether late corn planting will be 10 percent or more above average, where the negative impact on corn yield is relatively large. Specifically, when late planting is 10 percent or more above average the chance of corn yield being below trend is 83 percent and the average deviation from trend yield is –6.1 bushels per acre. We analyze topsoil surplus moisture patterns in analog years to 2019 and the analysis suggests late planting this year is likely to be at least 10 percent. The implication is that there is a significantly elevated probability of a below-trend corn yield in 2019 and that present projections of U.S. average corn yield should likely be reduced to 170 bushels per acre or less. It is important to recognize that good summer weather conditions can offset the projected negative impact of late planting on the national average corn yield, but history indicates the probability of this happening is not very high if wet conditions in the Corn Belt persist through mid-May.” - Irwin and Hubbs, University of Illinois

Crop Insurance Loss Ratios in 2018

Gary Schnitkey from the University of Illinois discusses crop insurance loss ratios for 2018, the current outlook for payments in 2019, and the strategic economic models he’ll be developing for soybeans.

by Gary Schnitkey, University of Illinois
link to farmdocDaily article

Most 2018 payments on Federal crop insurance products have now been entered into the Risk Management Agency’s (RMA’s) record system and losses for 2018 can be stated accurately. Similar to 2016 and 2017, low losses again occurred in 2018. Losses were particularly low in Illinois and, more generally, the eastern Corn Belt.

Background on Loss Ratios

This article presents loss ratios, which equal payments on crop insurance policies divided by total premium paid on crop insurance policies. A loss ratio of 1.0 means that crop insurance payments are equal to total premium. Ratios above 1.0 indicate that payments exceed premium, which occurs with some regularity. On the other hand, loss ratios below 1.0 indicate that payments are less than premium. Given the way RMA sets premiums, loss ratios should average slightly below 1.0 over time. Given the high correlation of losses across policies in a year, variability in aggregate loss ratios will occur from year to year.

Data reported in this article come from the Summary of Business which is available from the RMA website. Data were downloaded in late April of 2019. Some changes to loss ratios will occur over time as more loss data become available. However, 2018 loss performance will not materially vary from loss ratios presented here.

Loss Ratios in 2018

For all insurance products, the 2018 loss ratio was .69, indicating that crop insurance payments were less than total premium. Overall, 2018 was a low loss year, continuing a string of low loss years that have occurred since 2013 (see Figure 1). Loss ratios exceeded 1.0 in the drought year of 2012 when the overall loss ratio was 1.57. Payments also exceeded premium in 2013 when the loss ratio was 1.03. Since 2013, loss ratios have been below 1.0 in each year: .91 in 2014, .65 in 2015, .42 in 2016, .54 in 2017, and .69 in 2018. These low loss years correspond to relatively high yielding years in corn and soybeans (farmdoc daily, April 16, 2019).

The overall loss ratio is highly influenced by the performance of corn and soybeans, as these two crops account for 56% of total premium. In 2018, corn policies had 32% of total premium while soybeans had 23%. In 2018, loss ratios were .43 on corn and .56 on soybeans. Since 2014, both crops have had low loss ratios. Corn loss ratios were .46 in 2015, .27 in 2016, .37 in 2017, and .43 in 2018. Soybean loss ratios were .55 in 2015, .21 in 2016, .30 in 2017, and .56 in 2018.
2018 Loss Ratios by County

Many counties in the Corn Belt had very low loss ratios, as would be expected given that corn and soybeans have very low loss ratios. Figure 2 shows loss ratios by county for all policies in that county. Loss ratios below .4 predominated in a stretch of counties beginning in eastern Iowa, going through Illinois, Indiana, and ending in Ohio. Low loss ratios also were in western Corn Belt counties including Minnesota, North Dakota, South Dakota, and Nebraska. In contrast, there was a concentration of counties along the Iowa-Minnesota border that had higher loss ratios above 1.0.

Other sections of the country had higher loss ratios. Loss ratios above 1.2 predominated in North and South Carolina, Georgia, Florida, northwest Missouri and eastern Kansa, and western Texas.
Summary

Overall, loss ratios were low in 2018, continuing a string of years since 2014 that have had low loss ratios. Low loss ratios occurred primarily because of low losses on corn and soybean policies in the Corn Belt.

It Still Takes Two Weeks to Plant the American Corn Crop

Most people take for granted that the farmers can plant their crops way faster today than ever before. While it is true today’s equipment can plant a single acre of corn much faster, it still takes about the same amount of time to plant the whole crop.

It’s an illusion and pretty simple math says University of Illinois Agricultural Economist Scott Irwin, "This is a situation where your eyes can deceive you. So, you drive out in the countryside and you have a friend that is a farmer. They have a big planter and can plant their individual farm, in these particular cases, clearly much faster than they used to (be able to plant them). I don’t disagree with that individual anecdotal observation. The problem is that this doesn’t necessarily add up to the whole."

Sure, the equipment can get over a single acre way faster but each piece of equipment is going over way more acres than used to be the case. Consequently, it takes about the same time to plant the whole U.S. corn crop today as it did forty-years ago says Irwin, "It is a near constant, there is some variation from year to year, but on average it looks like it takes a minimum of 14 good field days to get the U.S. corn belt planted with basically everyone able to, and willing to, run flat-out."

In 1980, for instance, Illinois farmers were able to plant about one-million acres per day. Last year, running flat-out that figure was approximately the same.

Good Yields! Yes but a Warning | an interview with Gary Schnitkey

by Gary Schnitkey, University of Illinois
read farmdocDaily article

On a national basis, corn and soybean yields were near record-breaking levels in 2018, with exceptional yields in central Illinois and the eastern United States contributing heavily to those near-record U.S. yields. Other areas had below-trend yields. The county yields for corn and soybeans presented in this article illustrate these facts. Much higher U.S. yields are possible if all areas have exceptional yields. However, all areas including Illinois should not expect above-trend yields in every year.

Corn Yields

The 2018 corn yield for the United States was 176.4 bushels per acre, just .2 bushels below the record yield of 176.6 bushels per acre set in 2017 (all yields in this article are from QuickStats, a website maintained by the National Agricultural Statistical Service). From a national standpoint, corn yields were excellent in 2018.

Contributing to these high yields were counties having average yields above 220 bushels per acre. Several of these counties were in the Northwest U.S. and Nebraska where irrigation often is used in corn production (see Figure 1). In predominately non-irrigated counties, there were a concentration of counties in eastern Iowa and extending through central Illinois with over 220 bushels per acre average yields (see Figure 1). Three counties in this region, all in Illinois, had average yields over 240 bushels per acre: Douglas County (246.0 bushels per acre), Piatt (241.8), and Warren (241.7). Eleven counties – again, all in Illinois – had average yields between 230 and 240 bushels per acre: Macon (239.9), Sangamon (236.4), Logan (236.2), Tazewell (235.4), Effingham (235.2), Coles (234.2), Stark (234.0), Moultrie (233.9), Hancock (233.9), Christian (232.9), and Mercer (231.3). Eighteen counties had yields between 220 and 230 bushels per acre: 6 counties in Iowa and 12 in Illinois.

High yields are a measure of good growing conditions, but it does not take into consideration the inherent productivity of soil. Yield deviations from trend consider an area’s productivity. For each county, a 2018 trend yield was calculated using linear regression to fit a straight line through actual county yields from 1972 to 2017. The straight line then was extended to give the 2018 trend yield which represents the expected yield given approximately average growing conditions. A yield deviation then equals the actual yield minus the trend yield. A yield deviation of 20 bushels per acre means the actual 2018 yield is 20 bushels higher than the trend yield, an indicator of a very good yield. Conversely, a –20 yield deviation indicates that the county yield is 20 bushels below the trend yield, an indicator of poor growing conditions.

As would be expected, eastern Iowa and central Illinois had yields with positive yield deviations, with many counties having yield trends above 30 bushels per acre (see Figure 2). Note that yield deviations paint a broader area of excellent yields. That area includes southern Illinois, central and southern Indiana, western Ohio, western Kentucky, and parts of central Tennessee.

Other areas did not fare as well. Counties along the Iowa-Minnesota border had below-trend yields (see Figure 2). Other regions of poor yields in include Colorado, eastern Kansas and western Missouri, Texas, Arkansas and Louisiana, North Carolina, and New York.
Soybeans Yields Similar to corn, soybeans almost had a record-breaking yield. The average U.S. soybean yield for 2018 was 51.6 bushels per acre, .3 bushels below the record yield set in 2016 of 51.9 bushels per acre.

There were many areas of exceptional soybean yields (see Figure 3). Twenty-nine counties had average county yields over 70 bushels per acre. Three of these counties were in Nebraska: Gosper (75.2 bushels per acre), Dawson (73.2), and Buffalo (70.6). The remaining 26 counties were in Illinois. Three Illinois counties had average county yields over 80 bushels per acre: Sangamon County (82.3 bushels per acre), Morgan (81.6), and Douglas (80).

Yield deviations suggest that central and southern Illinois had exceptional growing conditions in 2018 (see Figure 4). Excellent growing conditions continued into Indiana, Ohio, Kentucky, and Tennessee. Other areas did not have as productive of a year. Yields were below trend along the Iowa-Minnesota board, North and South Dakota, Nebraska, Wisconsin, Michigan, Pennsylvania, and in North and South Dakota.

Commentary The U.S. had near-record yields for corn and soybeans in 2018. Above-trend yields in central and southern Illinois, central and southern Indiana, western Ohio, Kentucky, and Tennessee where large contributors to the near-record U.S. yields.

The examination of county yields suggests two warnings. Illinois farmers should note that many several areas in the country had below-trend yields in 2018. Therefore, the 2018 experience indicates that below-trend yields are still possible. Illinois farmers should not plan on having above-trend yields in every year. It is entirely possible that the area of below-trend yields centered along the Iowa-Minnesota border in 2018 could occur in central Illinois. At the same time, Iowa and Minnesota could have above-trend yields. If that reversal occurs in 2019, there would be large, negative incomes on many Illinois farms.

Somewhat counter to the first warning, the second warning is for the possibility of much larger national corn and soybean supplies. It is possible that all areas of the U.S. have above-trend yields. That is, the western Corn Belt could have had above-trend yields at the same time the eastern Corn Belt has above-trend yields. If this occurs, national yields would be record-breaking, resulting in falling corn and soybean prices, leading to very low farm incomes.

Apr 10 | CONAB Updates Corn S&D Table

@Conab_Oficial reports Brazil's second-crop corn acreage is expected to be up 6.1% from last year. An early soybean harvest and good weather are the contributing factors. The 2nd crop corn harvest is expected to be 26.4% larger than last season's climate hampered crop.

Brazil's 2018/19 ending stocks are expected to rise to 15.3mt or approximately a 2-month supply with total yearly demand at 93.5mt. @Conab_Oficial notes new crop corn supply may yet grow as production conditions are "very positive". Exports are set at 31mt.

On price - @Conab_Oficial is concerned domestic usage will not increase because the 62.5mt already includes livestock feed usage that has levelled off and it is not known if domestic corn ethanol increases will materialize as new plants have yet to come online.

...a good part of the 1st crop corn writes @Conab_Oficial has not been marketed. When taken with a big second crop corn harvest it cautions a low price scenario.

Brazil's counterpart to USDA @Conab_Oficial notes early season conditions in the United States, should the over-abundant rainfall continue, could cause a switch to soybean acres here and a lower @CMEGroup futures price.

USDA Reports Provide Surprises for Corn

Friday’s USDA reports surprised the corn market. Todd Gleason has more on how more corn acreage than expected this year coupled with more corn leftover from last year than expected will influence prices.

by Todd Hubbs, University of Illinois
read farmdocdaily article
watch post-USDA report webinar with Todd Hubbs and Scott Irwin

The USDA’s quarterly Grain Stocks report and annual Prospective Planting report delivered surprises to the corn market. A greater than expected corn stocks number combined with higher than expected planted acreage of corn gave very bearish news to corn prices. Soybean stocks and acreage came in neutral to slightly positive for soybean prices.

March 1 corn stocks came in at 8.605 billion bushels compared to an average trade guess of 8.335 billion bushels. The stocks estimate suggested feed and residual use of corn during the first half of the 2018–19 marketing year came in eight percent lower than last marketing year. Lower feed and residual use materialized despite a sizable livestock herd and reduced production of distiller’s grains on weakening ethanol grind. A higher stocks estimate suggests the potential for underestimation of the 2018 crop size and supports the notion of declining demand for corn during the second quarter of the marketing year.

Corn producers reported intentions to plant 92.8 million acres of corn this year, 3.66 million more than planted last year. The reported corn acreage exceeded trade expectations by 1.4 million acres. The intention to increase corn acreage is widespread throughout the Corn Belt. Acreage is up 400,000 acres in Iowa, 200,000 in Illinois, and 150,000 in Indiana. Significant increases in corn acreage intentions showed up in the Northern Plains with North Dakota intending to plant 900,000 additional acres and South Dakota up 700,000 acres. Overall, the top ten corn producing states increased acreage by 2.05 million acres. If the intention to plant 92.8 million acres materializes, harvested acreage for grain may be close to 85.4 million acres. A U.S. average yield near 174.6 bushels per acre leads to a projection of production in 2019 of 14.9 billion bushels. Corn production at this level exceeds current marketing year use projections by 300,000 bushels. Corn use is expected to be higher in the 2019–20 marketing year, but the current implication of slowing use in the current marketing year and a larger crop next year is higher ending stocks.

The soybean stocks report appears neutral for soybean prices. March 1 soybean stocks estimates indicated 2.72 billion bushels, which came in above trade expectations by 33 million bushels. The stocks estimate implies seed and residual use of soybeans during the first half of the marketing year at 203 million bushels. Seed and residual use is up from last year and at the highest levels since the 2014–15 marketing year. The implications for soybean use this marketing year remain at previous levels and continue to rely on a resolution to trade issues.

Soybean planting intentions indicated farmers plan to plant 84.6 million acres of soybeans, down 4.6 million acres from last year. The soybean acreage intentions came in 1.55 million acres below of market expectations. Intentions to reduce soybean acreage spans most major production regions. In major producing states, the intention to plant fewer soybean acres is indicated by 300,000 fewer acres in Illinois, 600,000 in Iowa, and 500,000 in Minnesota. If 84.6 million acres are planted, harvested acreage could be close to 83.6 million acres. At a U.S. average yield of 49.4 bushels per acre, 2019 production projects to 4.13 billion bushels, 88 million bushels larger than current marketing year use projections. Without a significant change in soybean use over the next year, ending stocks appear set to increase slightly.

In addition to the allocation of acreage to corn and soybeans, the magnitude of total principal crop acreage shows a 4.2 million acre decrease from 2018. The USDA estimates that acreage planted to principal crops totals 315.4 million acres. The planned reduction in total planted acreage from that of a year ago showed up in feed grain crops other than corn. Sorghum acreage is projected to be 555,000 acres lower than a year ago at 5.18 million acres. Wheat acreage decreased two million acres to 45.8 million acres. Oat acreage declined by 191,000 acres. Acreage of oilseeds other than soybeans is projected to fall by 15,000 acres. Harvested acreage of hay is expected to increase by 215,000 acres.

The surprise in March 1 stocks and acreage created a bearish scenario for corn prices. The large corn stock number influences the consumption of corn in the feed and residual category directly during the current marketing year. An expectation of reduced feed and residual use is prudent moving forward. Without a resolution to the trade dispute, growth in ending stocks in both corn and soybeans appears feasible over the next year. Planting intentions confirmed the belief that farmers would switch to corn production in 2019. Depending on field conditions during the planting season and the changing price relationship between crops, the possibility of greater soybean acreage than reported in March exists. The June Acreage report will provide more clarification.

Managing Nitrogen for Corn in 2019

by Emerson Nafziger, University of Illinois

The fall of 2018 and so far in 2019, there have been limited opportunities to apply nitrogen fertilizer. Average rainfall through the first 25 days of March ranged from a little less than normal in the northern half of Illinois to an inch or more above normal in south-central Illinois. But temperatures have averaged 3 to 4 degrees below normal, which slowed drying. There were several days in the first week of March when it was frozen on the surface and a considerable amount of P and K went on. This was followed by an inch or more of rain (which had been forecast) in many areas, and it’s likely that some of the nutrients—those in MAP/DAP and potash are soluble—moved from higher to lower parts of fields, or off of fields altogether. While it’s good to get P and K applied before spring work starts, we really should consider holding off the next time soils are frozen and substantial rainfall is forecast before a thaw.

N rate

Results from the on-farm trials coordinated by Dan Schaefer of the IFCA and funded in part by the Illinois Nutrient Research & Education Council (NREC) showed that at about two-thirds of Illinois sites in 2018, the N rate needed to maximize the dollar return to N was higher than we have typically seen. We think that the slow start to mineralization during the cool weather in April 2018 might have meant more dependence on fertilizer N. Yields were also higher than we’ve usually found, which meant that the crop took up more N than usual.

Adding the 2018 data to the database used by the N rate calculator to calculate best (MRTN) rates for N in Illinois, and taking out some older data, resulted in an increase in the MRTN values compared to the previous (2018) version for corn following soybean. With N priced at $615 per ton of anhydrous ammonia ($0.375 per lb of N) and corn at $3.75 per bushel, the calculator gives MRTN rates for corn following soybean of 166, 180, and 192 lb N per acre for northern, central, and southern Illinois. These rates are 11 lb higher than the 2018 rates in northern and southern Illinois, and 5 lb higher in central Illinois. Those are modest changes because the 2018 data is added to a lot of existing data, but they illustrate how generating and adding new data keeps the guideline N rates responsive to research-based changes.

MRTN values for corn following corn did not change very much, in part because there weren’t as many trials in 2018, and in part because trials over the over the past several years have shown that corn following corn has required less fertilizer N than we found in many previous trials. It’s not clear why that is the case, but as we found with corn following corn, rates are responding to research findings to stay linked to what today’s corn crop needs.

Remember that the MRTN rates (and ranges) generated by the N rate calculator include all of the N that gets applied, not just to the main application. A 3-year, NREC-funded trial at two sites that we finished in 2018 showed that N rates from DAP applied in either the fall or in the spring produced the same yield response to N as spring-applied UAN. This means that we should be able to take full credit for N from MAP or DAP, providing these are applied after soils cool in the fall (about November 1 or later) or any time before planting in the spring. If these P fertilizers are applied before soils cool in the fall, some of the ammonium will convert to nitrate and be subject to loss. It’s reasonable to subtract maybe 20 to 30% of the N from P fertilizers that are applied in early October, before soils start to cool down.

N timing

In about 90 percent of on-farm trials comparing N rates applied as ammonia in both the fall (with N-Serve) and the spring, we have found little or no difference in yield responses to N rate. That’s been the case in our N-tracking trials as well: we generally find nearly all of the fall-applied N still present in the soil at planting (although most of it is usually in the nitrate form by then), and we have rarely found a yield advantage to applying 200 lb N in the spring compared to 200 lb N in the fall. Tile-drainage studies do show a little more N loss from fall-applied compared to spring-applied N, though, and we have found in a few cases either higher yields with spring-applied N or similar yields produced with lower rates of spring-applied N.

We have also found in a few trials the opposite—that fall-applied N can sometimes give higher yields or need less N to produce the same yield as spring-applied N. This is more likely when N rates needed to maximize the return to N are not unusually high, and when spring-applied N is applied at or after planting, with some delay in how soon the crop’s roots can reach the application band to start taking up N. That is, having the N dispersed in the soil after application under better (drier) soil conditions in the fall may sometimes be an advantage compared to application into wetter soils in the spring. Wet fall weather like we had in 2018 likely means less chance of seeing such an advantage in 2019. We did not get many trials established last fall to make the comparison.

There is no reason to expect that the delay in N application in most Illinois fields so far this season will lower yield potential, but it will be important to keep a couple of things in mind as the planting season approaches. The main lesson we’ve learned from our N timing and N form studies over the past five years is that corn plants need to have a substantial amount of N available in the soil near the row after plants emerge and before their nodal (main) root system starts to develop.

Table 1 shows yield averages from 15 site-years over the past four years (2015-2018) at four Illinois sites where corn followed soybean. The highest yields (those followed by an “a”) all came from treatments with 100 or 150 lb of N applied at planting, and applied in a way that we think made N available to the plants soon after emergence. Among the treatments with all 150 lb N applied at planting, broadcast SuperU (urea with both urease and nitrification inhibitors incorporated) and ESN (polymer-coated urea with extended release) produced the highest yields. Those that included N applied between the rows—especially NH3 with or without N-Serve, which would have been accessible to the roots only once the roots grew out to the band, yielded a little less. Adding nitrapyrin (Instinct) to UAN injected between the rows lowered yield a little, and those that had UAN surfaced-applied all yielded less: these may have lost some N or the N might have moved too slowly from the surface to the root zone to maximize yield.

Treatments with 150 lb N split into 100 lb at planting and 50 lb applied in-season generally yielded a little more than applying all of the N between the rows at planting (Table 1.) Applying 50 lb N as broadcast UAN at planting (to mimic the use of UAN as herbicide carrier at or after planting) then 100 lb as UAN injected at stage V5 did not yield very well, possibly because some of the N might have been lost, but more likely because there wasn’t enough N near the root system when it was needed, before sidedress. Otherwise, most of the treatments with 100 lb injected at planting followed by 50 lb as urea with Agrotain broadcast at V5 or V9, or as UAN dribbled in-row at V5, V9, or at tassel (VT) stage did well. Waiting until V9 and dribbling all 150 lb N as UAN at V9 was the lowest-yielding treatment, likely due to development of N deficiency (whether visible or not) that lowered yield potential in earlier stages. Injecting all of the N mid-row at V5 yielded as well as injecting 100 lb at planting and 50 at V5, which is counter to the idea that the crop needs more N early. We don’t know the reason for this.

Table 1. Corn yields with different forms and timing of 150 lb N/acre in corn following soybean. Data are averaged over 15 sites, with 3 or 4 sites per years for 4 years, 2015-2018. Averages followed by the same letter are not significantly different at the 10% (error) level.

Another piece of evidence that the crop needs a good supply of N relatively early to avoid lowering yield potential comes from a part of the same N form and timing study reported in Table 1. Averaged across 18 site-years, applying 100 lb N at planting yielded 13 bushels more (214 versus 201) than applying 50 lb at planting plus 50 lb (as injected UAN) at sidedress, stage V5-6. At rates of 150 and 200 lb N/acre, applying 50 lb at planting then the rest at sidedress yielded about 3 bushels less than applying all of the N at planting. At the 200-lb rate, applying all of the N early yielded significantly more than the 50+150 split at two sites, and the split N yielded significantly more than the all-early application at one site.

In another set of trials, 200 lb N as fall-applied ammonia with N-Serve yielded an average of 5 bushels more than 50 lb N as injected UAN at planting followed by 150 lb N as injected UAN at sidedress. The 50-150 split-sidedress treatment yielded more than fall-applied N at most sites in 2015, when June was very wet, but the 50-150 split yielded less than fall-applied N at most sites in both 2017 and 2018. This shows that applying some of the N at sidedress can bring yields up close to those from all-early application of the same rate, but keeping back most of the N to apply in-season is more likely to decrease yields than to increase yield compared to applying all of the N before planting, including in the fall. If we do sidedress, we need to apply at least half of the N where the roots of small plants can get access to it in order to prevent early-season deficiency that can result in lower yields.

We also noted that when we get really wet soil conditions in June after the crop has started to grow, like we had in 2015, split-sidedress N can outperform all-early N. Under these conditions, the crop may well need more N than we have (or would have) applied. In order to respond to added N under wet conditions, the crop needs to have its root system active, which won’t be the case if it’s still standing in water or saturated soils. Also, if the lower leaves have started to die off, the plant may not be able to take up and utilize added N. Even then, a period with the roots under low oxygen conditions may not yield fully, even if soil conditions improve. It’s important to get supplemental N applied as soon as possible so that the crop can take it up as soon as it’s able. Dropping urea (perhaps with urease inhibitor) from the air is expensive, but might be in order, especially if a planned sidedress application wasn’t made before it got wet.

N form and additives

Different forms of N fertilizer need to be applied in a way that assures crop safety and maximizes the chance that the N will be available to the crop when the crop needs it. Anhydrous ammonia is usually the N source with the lowest cost (per pound of N) and at 82% N, using ammonia means less volume to store and transport. But it requires injection to depth in the soil, and so is more costly to apply. It also needs to be handled very carefully to prevent accidental release into the air. Once in the soil, it spreads (in soils not too dry or too wet) several inches out onto the soil and, by desiccating soil microbes, it limits microbial activity that converts ammonium to nitrate; that is, ammonia partially sterilizes the soil, in the process limiting its own conversion to nitrate for a period of time. Conversion to nitrate makes N mobile in the soil, and nitrate is subject to loss by leaching and denitrification. This isn’t permanent: these microbes grow back quickly in the presence of so much N, and eventually reach levels higher than before the ammonia was applied.

We normally use a nitrification inhibitor such as N-Serve or CENTURO (new from Koch Agronomic Services) when applying ammonia in the fall. The later we apply ammonia in the spring the less likely it is that a nitrification inhibitor will be needed to help keep N in the (immobile) ammonium form, and thus in rooting zone. As a biological process, nitrification is slow in cool soils, which usually means it’s slow through most of March. Illinois State Water Survey data show that at Bondville, just west of Champaign, 4-inch bare soil temperatures have been in the low 40s for the past two weeks. On average over the past five years, 4-inch soil temperatures have reached and then stayed above 50 degrees by about April 14 at this site, and it’s averaged about May 10 before soil temperature reaches and stays above 60. Nitrification is slow when temperatures are in the 50s, and begins to speed up once soil temperatures reach 60 and above. If we are able to plant more or less on time this year so that N uptake begins to accelerate in late May, and if we add in the effect of the NH3 itself in suppressing microbial activity, it’s unlikely that applications of ammonia made after April 1 will need the further delay in nitrification provided by nitrification inhibitor.

Because cool soils are slow to dry, applications of ammonia in the spring are usually done when soils are wetter than ideal. That doesn’t mean we should abandon this form of N, but applying it on wet soils means more soil compaction, and with the diameter of the ammonia band very small when application is into wet soil, its concentration is high. If the soil dries out after application, there is some danger than NH3 will begin to move up in the soil, and may damage seeds or roots. Using RTK to apply the band 6 to 8 inches away from where the row will be planted can eliminate such damage, but that means applying in the direction of the rows instead of on an angle. Tilling after ammonia application can also help disperse the band and will usually lower or eliminate the risk of ammonia injury on seedlings.

Dry urea has the advantage of being quick and easy to broadcast-apply with flotation equipment, and has the additional advantage of being safe to apply after crop emergence. If spread on the soil surface and worked in with a tillage pass before planting, it is relatively safe from loss by volatilization, which is breakdown into carbon dioxide and ammonia, which can be lost to the air. If surface-applied without incorporation, using a urease inhibitor will help decrease volatilization. Getting a half inch or more of rain will move most of the urea into the soil, where any volatilized ammonia will be quickly dissolved in soil water. Urea doesn’t “self-sterilize” the soil to limit nitrification like ammonia does, though, so with warm surface soil temperatures, nitrification will begin soon after the urea is dissolved and in the soil (as ammonium). In the results in Table 1, SuperU (from Koch), which has both urease and nitrification inhibitors, produced the highest yields of any of the forms and application methods used in that study. Urea with the urease inhibitor Agrotain yielded 5 bushels less, presumably because of some loss (or movement below the root zone) of N following nitrification; urease inhibitor has no effect on the nitrification process once the N is on the ammonium form.

N application

Application methods are discussed several places above for different N forms, so only a few additional things will be noted here. Most application methods are not new, but there have been some innovations in recent years that offer more options. One big issue 15 or 20 years ago, perhaps related to aerial imaging that showed colors patterns in corn fields, was that of uneven distribution of NH3 across the knives on toolbars. A number of engineering improvements since then have diminished, if not eliminated, this problem, and as long as older manifolds have been replaced, it’s not a major issue now.

Application depth of NH3 has some influence on back-pressure and distribution, and on how safe the ammonia is from release into the air. Under normal soil conditions (not too wet), releasing NH3 5 or 6 inches deep is a safe depth, but if it’s wet, that will place it deep enough so that roots of small plants may not get access to it as soon as they should. This can be overcome to some extent by application of some of the N in more-available forms, such as 2 x 2 placement with the planter. This should be done with enough of the N (50 lb or more) to support early growth. In-furrow application of starter fertilizer or broadcasting 10 to 15 gallons of UAN 28 (30 to 45 lb of N) with herbicide helps, but unless soils are warm enough so that mineralization has kicked in by the time plants are at the 2-leaf stage (normally 20 to 25 days after planting), these applications may not provide enough N in time to maximize yield potential.

While most in-season (or at-planting) applications of UAN solution have traditionally been made by shallow injection, the recent advent of near-row dribble (Y-Drop®) technology and similar equipment, in at least one case with the ability to apply both between-row injection and near-row dribble at the same time, offers a different option for placement. One advantage promoted for near-row dribble is the ability to apply N to corn of different sizes, from small plants to tassel stage or even beyond, using high-clearance equipment. This equipment has been promoted to some extent on the idea that “spoon-feeding”—applying N before and several times during the rapid growth/N uptake stages—can better match N to the crop’s needs, with less potential for loss, thereby maximizing yields. We have not found such an approach to be effective: as detailed above, we seldom (with some exceptions) find a yield advantage to keeping any of the N back for a single in-season application. And, we see no effective way to adjust N rates with later applications to end up lowering rates, thereby increasing N efficiency. We know beyond doubt that most soils are very effective as reservoirs for N, and this means that there is simply no yield advantage for breaking one or two N applications, including a major one at or soon after planting, into three or four applications. Without a yield advantage, the added application costs will lower returns.

As a way to apply in-season N, however, near-row dribble has some advantages over mid-row injection. Corn’s nodal roots grow down at an angle from the lower stem where they originate, so placement closer to the row means placement at less distance down to the root system. Dribbled UAN is also shaded a little more by the row so may be less prone to volatilization under high temperatures in direct sunlight. One question has been whether a near-row (or injected) UAN application made in-season will benefit from the addition of a urease inhibitor (like Agrotain) or even of a nitrification inhibitor (like Instinct). Injected UAN should never need a urease inhibitor, and if it’s dry and expected to continue to be dry, some consideration might be given to changing from dribbled to injected UAN. Until it rains, neither dribbled nor injected N will get to the roots for uptake, but at least the injected UAN-N won’t volatilize. It might make sense to use a urease inhibitor if surface application is the only option, but that won’t eliminate the risk that if it stays dry, the N won’t get into the crop in time to maximize its use no matter how we apply it. If it’s dry by early June and is projected to stay dry (as it did in 2012), it might make sense to skip the in-season N application altogether.

Dry urea can be applied across the top of emerged corn without concern for injury, although leaf edges sometimes show damage after application, especially when applied to larger plants, which catch more urea in the whorl. Some long-ago research showed that urea in the whorl didn’t decrease yield. Moderate wind tends to fold leaves over the whorl and may decrease urea capture, but of course won’t help uniformity of spread. Although urea applied to the soil surface is subject to loss by volatilization, enough rain to move the urea into the soil within a week after application will minimize losses. If it doesn’t rain, the urea may not do much good. Using Agrotain will help reduce volatilization and lower risk of loss, and might be appropriate if rain is likely to come late. Using polymer-coated urea (ESN) slows release of the urea into the soil, but in-season applications are usually made with the hope that N will get into the plants quickly, and slow-release will hinder that, and will lower effectiveness of the applied N. Polymer-coated urea can also move with surface flow of water following heavy rain, and in some cases might even leave the field.

While 2019 has so far presented some challenges in terms of applying N, a period of warm weather in April can greatly improve the prospect of getting N on this year’s crop without losing yield potential. We will need to retain flexibility, though, perhaps to the extent of changing form and timing of application to ensure that the crop gets enough N in time. One drawback to that, besides the challenges in equipment and timing, may be increased N costs that result from changing N form and application equipment. It would be good to enter revised N prices into the N rate calculator to see how this changes the amount of N to use. With expected corn prices and margins not very high, this might be the year to put off trying new and less-proven products and practices, and to focus instead on the basics of getting N to the crop in adequate amounts, both by choosing moderate rates (the MRTN should be the first option for most fields) and by applying N in a way that minimizes losses and maximizes crop access to this critically important nutrient.

Mar 29 | USDA Stocks & Acreage

- Dale Durchholz, AgriVisor LLC
- Greg Ginder, FCStone
- Mike Zuzolo, GlobalAnalytics.net
- Lance Honig, USDA NASS

Pre-Season Tar Spot Checklist for Corn

Corn farmers in northern Illinois and across the corn belt have been dealing with a new disease. Todd Gleason has more on Tar Spot and what producers can do to mitigate its impact.

Tar spot is a relatively new disease of corn in the Midwest. It has been showing up on field corn in Iowa, Illinois, Michigan, Wisconsin, Indiana, Ohio, and Florida says University of Illinois Extension Plant Pathologist Nathan Kleczewski, "That's where it is found right now. But in terms of severity, where we have seen it the most and the pressure is the highest, if you would take the lower portion of Lake Michigan and draw a section around there, that is where we've had the greatest severity right now. That is where we've had the most pressure."

Kleczewski says this is because tar spot likes nighttime lows in the 70's and a lot of humidity. Here's a pre-season checklist for farmers in these areas concerned about the disease, "We do know that hybrids have different tolerance to this disease. They are all susceptible but some are less susceptible than others. And if you can get information from seedsman as to the tolerance rankings, go with something that is less susceptible if it fits your production needs."

Wisconsin Extension Plant Pathologist Damon Smith has a list of some corn hybrid tolerances to tar spot. That list can be found on the Badger Crop Doc website. The address is badgercropdoc.com.

The Economic Advisability of Lowering 2019 N Rates on Corn

by Gary Schnitkey, Agricultural Economist - University of Illinois
read farmdocDaily article

Spring field operations will soon begin, and nitrogen applications on corn will commence. More nitrogen will be applied this spring than is typical because wet weather limited fall applications. University-recommended nitrogen application rates in Illinois are between 140 and 180 pounds of actual nitrogen per acre for corn-following-soybeans. For farmers applying above those rates, application reductions seem prudent this year. If a farmer is uncomfortable lowering to the University-recommended rates, experimenting by leaving strips in fields seems prudent.

Why Consider Lowering Nitrogen Application Rates in 2019?

Two economic factors suggest urgency in lowering nitrogen rates this year. First, net incomes on Illinois farms could be extremely low in 2019. Projections indicate average income on grain farms enrolled in Illinois Farm Business Farm Management (FBFM) could be -$55,000 per farm if prices maintain their current levels and yields are not exceptional (see farmdoc daily January 15, 2019). This average income would be the lowest since FBFM began collecting consistent income data starting in the 1970s. Although higher yields or higher prices could result in higher incomes, it seems more reasonable to expect very low incomes in 2019. Given these low incomes, reducing costs is crucial, particularly if those costs do not increase revenue.

Second, nitrogen fertilizer prices in 2019 have been increasing and will be above levels of the last three years (see Figure 1). On March 14th, the Agricultural Marketing Service (AMS) — an agency of the U.S. Department of Agriculture — reported an average anhydrous ammonia price in Illinois of $615 per ton, which is $97 per ton above the 2018 March average price of $518 per ton. The 2019 price also is above prices in March in 2016 and 2017 (see Figure 1). A higher nitrogen price suggests lowering applications, particularly given that the 2019 expected corn price is roughly at the same level as in 2017 and 2018.

Maximum Returns to Nitrogen (MRTNs) in Illinois

“Maximum Return to Nitrogen” (MRTN) rates are available from the Corn Nitrogen Rate Calculator, a website maintained by universities in Corn Belt states. MRTNs give the nitrogen rate that, over time, will produce the highest economic return for nitrogen use. Many nitrogen rate trials provide the basis for determining MRTNs (see the “About” section of Calculator for more detail).
Table 1 shows MRTNs from the Corn Nitrogen Rate Calculator for northern, central, and southern Illinois. These rates are shown for “corn-following-soybeans” and “corn-following-corn.” MRTNs also are given where the source of nitrogen is anhydrous ammonia and 28% nitrogen solution. Note that the rates in Table 1 include all sources of nitrogen, and credits should be given for nitrogen in DAP (see Using the N Rate Calculator).

Take Central Illinois as an example in interpreting the table. For corn-following-soybeans, MRTN rates are 174 pounds of nitrogen per acre for anhydrous ammonia and 163 pounds of nitrogen per acre for 28% nitrogen solution. Those rates are pounds of nitrogen applied per acre and not the amount of ammonia or solution applied. For anhydrous ammonia, the 174 pounds of nitrogen results in an application of 212 pounds of anhydrous ammonia (212 = 174 / .82 analysis of ammonia). For nitrogen solution, the application is 582 pounds per acre of 28% nitrogen solution (582 = 163 / .28).
Prices used in the calculations of MRTN rates in Table 1 are $3.70 per bushel for corn, $610 per ton for anhydrous ammonia, and $280 per ton for 28% nitrogen solution. Lower MRTNs result for 28% because nitrogen costs more in 28% than in anhydrous ammonia. The costs per pound of nitrogen in anhydrous ammonia is $.37 per pound ($610 price / (2000 pounds x .82 analysis)) compared to .50 per pound cost for 28% ($.50 = $280 / (2000 pounds x .28)).

PCM and Rates

Precision Conservation Management (PCM) is a farmer service program led by the Illinois Corn Growers Association in partnership with over 30 partners. The mission of PCM is to increase conservation practice adoption using farm business management principles. With 200 farmers enrolled in its 16-county service area, PCM represents about 200,000 acres of farmland in Illinois.
Farmers enrolled in PCM provide detailed production records geo-linked to fields, with data provided including nitrogen applied and yields. Data from 2015 through 2017 have been analyzed and suggest that many farmers apply above MRTN rates, with some exceeding 200 pounds of nitrogen per acre. In 2015 through 2017, higher than MRTNs did not lead to higher yields.
Costs of Over-applying

Applications of nitrogen above MRTNs have additional costs. Given the nitrogen prices above, every 10-pound application of actual nitrogen applied above the MRTN has a cost of $3.70 per acre for anhydrous ammonia and $5.00 per acre for 28%. For anhydrous ammonia, 1.0 additional bushel of corn is needed to compensate for the higher nitrogen costs. For 28%, 1.35 bushels of corn are needed to cover the costs of 10-pounds of additional nitrogen.

Costs increase as pounds of over-applications increase. Take a application that is 50 pounds above the MRTN. For 28%, this application will have an additional cost of $25 per acre. A farm with 1,000 corn acres would have $25,000 higher costs, and $25,000 less net income.

The MRTN takes into consideration many trials, and higher yields will occasionally occur at rates above MRTNs. Over time, however, profits should be maximized at rates near the MRTN (see N rate Calculator Updated). The $25 per acre costs would have to have an addition of 6.8 bushels to cover the cost if the yield above the MRTN was obtained each year. This break-even yield goes up if the yield does not increase each year. For example, the 6.8 bushels increase to 13.6 bushels per acre if the additional application only increases yield in 50% of the years. The break-even yield further increases to 27.0 bushels per acre if the yields respond only in one in four years.

Experimentation

The MRTNs in Table 1 may be considerably below the nitrogen rates used on many farms. Over time, applying above the recommended rate will result in lower profits. Given this fact, lowering applications to the MRTN rate seem prudent. If cutting applications to the MRTN seem extreme, experimentation may be warranted. Placing strips in fields at MRTNs may provide evidence that those rates do result in the most profit.

Farmers Unlikely to Make Big Acreage Switch to Corn

The scuttlebutt in the trade, even in the numbers released by USDA at its February Agricultural Outlook Forum, is that the economics will push farmers to plant a lot more corn acres this year.

Ag Economist Gary Schnitkey has updated budgets for corn and soybeans across the state. He knows USDA increased its expectation for corn acres around the nation by about 3 million acres but says he does not expect a big shift to corn in Illinois, “What we find is that corn is projected to be more profitable than soybeans. This is the first year in a while that has happened. However, our budgets do not suggest shifting to more corn production. Particularly corn-after-corn is less profitable than soybeans. So, it is status quo for the central Illinois area with a 50/50 corn/soybean rotation being more profitable for 2019.”

This holds for northern and central Illinois. Southern Illinois still has a regionalized economic bias to plant soybeans. Soybeans make more money there says Schnitkey, “However, the big thing right now is the upcoming USDA Prospective Plantings report and whether we will see shifts from soybean to corn which some people are expecting. These budgets would say in the heart of the corn belt, or in the corn belt in general, that you won’t see shifts from soybeans to corn. So, you have to see those shifts from someplace else and there are limited opportunities there.”

USDA in its February Outlook meeting projected U.S. farmers would plant about three percent more corn acres this season than last and almost five percent fewer soybean acres. The agency will release an official estimate of acreage March 29th.

Feb 23 | WILLAg Newsletter

Changes are coming!

The agricultural sector is caught up in a storm of change. Political and economic forces have been squeezing trade on the global front and U.S. farmers have been leaning into the winds. We take up a few of these topics in this edition of the WILLAg Newsletter.

Trade with China
Profile of USTR Lighthizer
USDA Ag Outlook Forum
Corn Acreage in 2019
Expected Corn vs Soybean Returns
2018 Ethanol Plant Losses

We’ll also explore these topics, marketing prospects, the price of farmland, and the weather during our March 5 All Day Ag Outlook. Hopefully, you can join us at the Beef House in Covington, Indiana. The cost is just $30 and includes Beef House coffee and rolls in the morning and Beef House lunch at the noon hour.

Tickets are available online or by calling 800–898–1065.

Hope to See You There!
Todd E. Gleason, Farm Broadcaster
University of Illinois Extension | WILLAg.org

Trade with China

Friday the Chinese trade delegation gathered in the Oval Office with President Trump. A letter from President Xi was read out loud. It urged a continued push toward a final trade deal. The only firm detail to come out of the week’s worth of talks in Washington was a commitment to purchase 10mmt of soybeans. USDA issued an official release on the announcement. It did not include a timeline for the purchases. CNBC reported the Chinese had offered to guarantee purchases of $1.2 trillion dollars of U.S. goods. Again, there was no timeline issued and this point has not been confirmed by any other outlet, the White House, or the Chinese.

During the week the trade discussions in Washington, D.C. pointed to five MOU’s. These Memorandums of Understanding included one on agriculture and were how U.S. Trade Representative Robert Lighthizer had decided to break down the issues in order to tackle them; agriculture, non-tariff barriers, services, technology transfer & intellectual property.

President Trump during the Oval Office meeting Friday pushed aside the MOU’s. He interrupted Trade Representative Lighthizer in front of the Chinese. Lighthizer was trying to explain how the MOUs would build the foundation of a trade deal. Mr. Trump stopped him and said, “I disagree. I think that a memorandum of understanding is not a contract to the extent that we want.” Lighthizer agreed that the term MOU would not be used again.

The important point in this exchange is likely not the MOU discussion. The President interrupted and corrected his lead trade negotiator in front of the Chinese delegation. Clearly, if a trade deal is to be struck it can only be done one-on-one between Presidents Trump and Xi. They may meet next month at Mar-A-Lago.

Mr. Trump has long focused on closing the trade gap with China. The other issues have not been of very much importance to him although he does mention China stealing and intellectual property rights. A trade deal with China is one of the President’s campaign promises. The dazzling $1.2 trillion number CNBC reported might be very enticing to a man who has had a habit of fulfilling his campaign promises.

If it is completed in this fashion, without enforcement mechanisms or real intellectual property rights protections, then as President Trump has said recently Democrats won’t go along. Republicans are likely to stay mum as the deal sets idle in Congress and simply becomes a presidential election year rallying cry. Presidents negotiate trade deals. Congress approves them.

Profile of USTR Lighthizer

NPR profiled Trade Representative Lighthizer this week. Please take six minutes to listen. It’ll be worth your while to know a whole lot more about the man leading the trade negotiations with China.

USDA Ag Outlook Forum

This week USDA put on its 95th Annual Agricultural Outlook Forum. It provides some initial numbers the trade uses to project the 2019 growing season into the markets until official USDA reports are issued. The first supply and demand report for the 2019/20 growing season will be issued in May. The March 29 Prospective Plantings report will provide survey results of what farmers think their acreage mix will look like this year. Here you will find some of the powerpoint slides U.S.D.A. Chief Economist Robert Johansson presented in the opening session and the full supply and demand tables presented Friday morning.

You may watch the full opening session of the 2019 USDA Agricultural Outlook Forum. It took place in Washington, D.C. February 21 and 22.

Corn Acreage in 2019

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The number of acres of corn planted this spring will be a key factor in determining where the price of corn goes. University of Illinois Agricultural Economist Todd Hubbs took up the issue in this week’s farmdocDaily article.

He starts with a historical graph. It shows the principal crop acres in the United States and how those have changed since 1997. Both corn and soybean acreage have increased. Combined they’re up about 10 percent over the past two decades.

Illinois’ Todd Hubbs uses that history to help put the number or corn and soybeans acres into perspective, “When we look at the harvest month corn to soybean futures price ratio this year it has been about 2.37. There is a definite signal in this graph from about 2006 to 2018 that if you are above 2.4 in that ratio, there will be less corn acreage. If you are below 2.3 there will be more corn acreage. We are, today, sitting right in between those. We’ve seen problems with field work in large parts of the corn belt. We’ve seen fertilizer and other input costs go up on corn. So, the idea that we are going to see a massive increase in corn acreage could happen, but under the current price structure we might not see the kind of corn acreage we think we are going to see.”

Hubbs says he used the 2019–20 futures prices to forward calculate a seasons average cash price for new crop corn. His calculation points to $3.81 per bushel. He then figured a stocks to use ratio that would fit that number, “I think an 11% stocks to use ratio in 2019–2020 would give us $3.81. If consumption is constant at 14.8 billion bushels from this marketing year to the next, that would put corn acreage around 91.7 million at a national trend line yield of 174.6 bushels to the acre.”

Finally, Hubbs says there isn’t a lot of weather premium priced into new crop corn futures. He also says there isn’t much of premium built in for a possible trade deal with China. Hubbs thinks that may be just as bullish for corn as it is for soybeans. Right now he thinks the 2.37 soybean/corn ratio feels high if the expectation is for a substantial increase in corn acreage.

Expected Corn versus Soybean Returns in 2019

by Gary Schnitkey, University of Illinois
see full farmdocDaily article and video

Two factors have changed between the planning periods in 2018 and 2019. First, expected soybeans prices are lower in 2019 as compared to 2018. A reasonable way of forming expectations of cash prices at harvest is to use current bid prices for fall delivery of grain. In 2018, fall delivery prices for soybeans in the month of February averaged about $9.80 in East-Central Illinois. In 2019, fall delivery prices are roughly $.75 per bushel less at $9.05 (see Table 1). At the same time, fall delivery prices for corn are roughly the same at $3.70 per bushel. An $.75 decline in soybean price reduces expected soybean returns by $45 per acre given a soybean yield of 60 bushels per acre ($45 = .75 lower price x 60 bushels yield).

Second, costs have increased, with a primary contributor being increases in nitrogen fertilizer prices. Throughout much of 2018, anhydrous ammonia prices were in the low $500 per ton range (see Table 2). So far in 2019, anhydrous ammonia prices have averaged $607 per ton in January and $613 in February (see Table 2). Fall applications of nitrogen were limited in 2018 due to wet soil conditions, leading many farmers to have to price nitrogen in 2019. These farmers likely will pay around $100 per ton more for anhydrous ammonia in 2019 as compared to 2018. If 220 pounds of anhydrous ammonia are applied per acre, leading to an application of 180 pounds of elemental N (180 = 220 pounds x .82 N analysis of anhydrous ammonia), nitrogen fertilizer costs would increase in 2019 over 2018 levels by $11 per acre ($100 price increase per ton x 220 pounds of anhydrous ammonia per acre / 2000 pounds per ton).

The decrease in soybean price increases the relative profitability of corn. The increase in nitrogen fertilizer price decreases the relative profitability of corn, partially offsetting the impacts if the soybean price increase.

2019 Corn and Soybean Budgets
Table 3 shows 2019 corn and soybean budgets for high-productivity farmland in central Illinois (see farmdoc for 2019 Crop Budgets). These budgets incorporate price and cost changes between 2018 and 2019. Two notes about these budgets:

Yields are 213 bushels per acre for corn-after-corn and 63 bushels per acre for soybeans-after-corn. These are trend yields. In recent years, yields in Illinois have been above trend. Corn yields averaged 20 bushels above trend from 2014 to 2018 (farmdoc daily, January 3, 2018) while soybean yields have averaged 6.5 bushels above trend (farmdoc daily, December 11, 2018).
Prices used in budgets are $3.60 per bushel for corn and $8.50 per bushel for soybeans. The corn price is near fall delivery bids while the budgeted soybean price is about $.55 per bushel below the fall delivery bid. The lower budgeted soybean price reflects a general pessimism about soybean prices resulting from expected large supplies relative to demand (see farmdoc daily, January 28, 2019). This lower soybean price will decrease soybean profitability relative to corn, suggesting more of a shift to corn than a higher soybean price.

Operator and land returns are $188 per acre for corn and $180 per acre for soybeans, suggesting that corn will be more profitable than soybeans. However, this difference in profitability does not suggest a large shift in acres to corn. Most farms in central Illinois have a corn-soybean rotation, necessitating a move to corn-after-corn to grow more corn. Corn-after-corn returns are projected at $137 per acre, which are less than the $180 per acre soybean-after-corn return. These lower corn-after-corn returns suggest maintaining a corn-soybean rotation.

Other Budget Values Operator and land returns shown in Table 3 were recalculated for two different scenarios. First, a $9.00 soybean price was used to calculate soybean returns. The $9.00 price is close to fall bids. Given that corn prices do not change, operator and land returns for corn remain the same as those shown in Table 3:

corn-after-soybeans: $188 per acre, and
corn-after-corn: $137 per acre,

while soybean returns increase to:

soybeans-after-corn: $211 per acre, and
soybeans-after-two-years-corn: $229 per acre.

As would be expected, this price scenario increases soybean profitability relative to corn. Current forward bids do not suggest a shift to corn from a profitability standpoint.

The second scenario maintains the corn and soybean prices at $3.60 and $8.50, respectively, but increases corn yields by 20 bushels per acre and soybean yields by 6 bushels per acre. This scenario reflects a situation where budgets are more optimistic than trend yields due to high yields in recent years. In this case, operator and land returns are:

corn-after-soybeans (233 bushels per acre): $260 per acre
corn-after-corn (223 bushels per acre): $209 per acre
soybeans-after-corn (69 bushels per acre): $231 per acre
soybeans-after-two-years-corn (71 bushels per acre):$248 per acre

Higher yields increase returns and also increase the relative profitability of corn. However, corn-after-scorn is less profitable than soybeans-after-corn. These projections do not suggest that growing more corn would be more profitable than maintaining soybean acres given that both crops have above trend yields at 2013–2018 levels.

Summary and Conclusions
Current fall delivery prices do not suggest that switching to more corn away from soybeans will result in higher profitability on high-productivity farmland in central Illinois. Due to high relatively corn yields, central Illinois is one of the most profitable areas to grow corn relative to soybeans, If central Illinois budgets do not suggest a switch to corn, budgets in less productive areas likely will not suggest a shift from soybeans to corn.

2018 Ethanol Plant Losses
see full farmdocDaily article

University of Illinois Agricultural Economist and noted ethanol industry specialist Scott Irwin wrote an article detailing the financial losses the industry experienced last year. Use the link above to read the full article. Here’s the paragraph Irwin penned on the potential implications for ethanol going forward.

“The ethanol industry in 2018 experienced its first losing year since 2012, thereby ending a run of five consecutive years of positive returns. The estimated loss for a representative Iowa ethanol plant in 2018 was -$2.2 million. While large, the 2018 loss was still far less than the -$6.7 million loss in 2012. The evidence points to overproduction as the driving force behind the low prices and financial losses experienced by ethanol producers during 2018. The fortunes of the U.S. ethanol industry are unlikely to improve until production and use are better balanced. This will require shuttering some production capacity, additional demand, or some combination of the two. The most optimistic scenario is additional demand for U.S. ethanol exports as part of a trade deal with China.” - Scott Irwin, University of Illinois