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C.O.R.N. Newsletter: 2018-10

  1. Adjusting Corn Management Practices for a Late Start

    Author(s): Steve Culman, Peter Thomison

    As prospects for a timely start to spring planting diminish, growers need to reassess their planting strategies and consider adjustments. Since delayed planting reduces the yield potential of corn, the foremost attention should be given to management practices that will expedite crop establishment. The following are some suggestions and guidelines to consider in dealing with a late planting season.

    Although the penalty for late planting is important, care should be taken to avoid tillage and planting operations when soil is wet. Yield reductions resulting from "mudding the seed in" are usually much greater than those resulting from a slight planting delay. Yields may be reduced somewhat this year due to delayed planting, but effects of soil compaction can reduce yield for several years to come. Keep in mind that we typically do not see significant yield reductions due to late planting until mid-May or even later in some years. In 2017, favorable growing conditions allowed many growers to achieve exceptionally high corn yields as late as early June.

    If you originally planned to apply nitrogen pre-plant, consider alternatives so that planting is not further delayed when favorable planting conditions occur. Although application of anhydrous N is usually recommended prior to April 15 in order to minimize potential injury to emerging corn, anhydrous N may be applied as close as a week before planting (unless hot, dry weather is predicted). In late planting seasons associated with wet cool soil conditions, growers should consider side-dressing anhydrous N (or UAN liquid solutions) and applying a minimum of 30 lb/N broadcast or banded to stimulate early seedling growth. These approaches will allow greater time for planting. Similarly, crop requirements for P and K can often be met with starter applications placed in bands two inches to the side and two inches below the seed. Application of P and K is only necessary with the starter if they are deficient in the soil, and the greatest probability of yield response from P and K starter is in a no-till situation.  Remember the longer our planting is delayed, the less beneficial a starter with P and K will be, because later planting dates typically have higher soil temperatures.

    Keep time expended on tillage passes and other preparatory operations to a minimum.  The above work will provide minimal benefits if it results in further planting delays. No-till offers the best option for planting on time this year. Field seedbed preparation should be limited to leveling ruts that may have been left by the previous year’s harvest - disk or field cultivate very lightly to level. Most newer planters provide relatively good seed placement in "trashy" or crusted seedbeds.

    Don't worry about switching hybrid maturities unless planting is delayed to late May. If planting is possible before May 20 to 25, plant full season hybrids first to allow them to exploit the growing season more fully. Research in Ohio and other Corn Belt states generally indicates that earlier maturity hybrids lose less yield potential with late plantings than the later maturing, full season hybrids. Also, remember that later planting dates generally increase the possibility of damage from European corn borer and western bean cutworm and warrant planting Bt hybrids that provide protection from these lepidopteran pests if suitable maturities are available.  

    In delayed planting situations, consider the optimal seeding rates for the yield potential of each field. Recommended seeding rates for early planting dates are often 5-10% higher than the desired harvest population to account for reduced germination and greater seedling mortality. However, soil temperatures are usually warmer in late-planted fields, and as a result, germination and emergence should be more rapid and uniform. So, as planting is delayed, growers may be able to reduce seeding rates in anticipation of a higher percentage of seedlings emerging. Adjust seeding depth according to soil conditions and monitor planting depth periodically during the planting operation and adjust for varying soil conditions. Planting depth recommendations for corn in Ohio are 1.5 to 2 inches deep to ensure adequate moisture uptake and seed-soil contact. Planting shallower than 1.5 inches is generally not recommended at any planting date or in any soil type. Deeper planting may be recommended as the season progresses and soils become warmer and drier.

  2. Using the Slake Test to Determine Soil Crusting

    Author(s):

    An easy to use test can be done to predict potential soil crusting on farm fields.  All you need is some chicken wire, water, a glass jar, and a dry clump of soil.  When you immerse the clump of soil in the jar of water, the longer it holds together, the better the soil structure to resist crusting. 

    The slake test compares two chunks of topsoil in water to see how well and how long they will hold together. Here are the steps according to NRCS Newsletter article #14:

    1. Collect a chunk of topsoil––a size that would fit in your hand––from an area where you do not till, like a fencerow, or a field you have no tilled or had in grass for many years.

    2. Get a second spade-full or chunk of soil from a field you have tilled consistently. It should be the same soil type as the first sample.  Both soil chunks need to be air-dry.

    3. Find two glass jars, canning jars or some kind of clear glass jars large enough to hold the chunks of soil.

    4. Put together some type of wire mesh that you can hook at the top of each jar that will allow the soil to be submerged in the water, yet be held within the top half of the jar.  Chicken wire works well.

    5. Insert the wire meshes into each jar.

    6. Fill the jars with water.

    7. At the same time, submerge the tilled sample in one jar, and the untilled sample in the other.

    8. Watch to see which soil holds together and which one falls apart. The soil with poor structure is the one that will begin to fall apart.

    Poor structure soil that easily falls apart will form small soil aggregates, which collect at the soil surface and will dry into a hard crust.  Crusted soil will make it difficult for seed emergence and will limit future rainfall infiltration and cause runoff and erosion. 

    Slaking indicates the stability of soil aggregates resistance to erosion and suggests how well soil can maintain its structure to provide water and air for plants and soil biota when it is rapidly wetted. Limited slaking suggests that organic matter is present in soil to help bind soil particles and micro aggregates into larger, stable aggregates.  During heavy rainfall events, a soil with good aggregate stability will maintain pore space and allow water to be absorbed into the soil. 

    Conservation tillage systems, such as no-till, reduce slaking by reducing soil-disturbing activities that break aggregates apart and accelerate decomposition of organic matter. No-till and residue management lead to increased soil organic matter and improved aggregate stability and soil structure, particularly when cover crops or sod-based rotations provide an additional source of residue.

    So observe what happens during heavy rainfall events.  Does your field flood or can it absorb the water?

    RESOURCES

    Why is Soil Organic Matter So Important?   Hatfield et al., Crops & Soils Magazine, March-April 2018, pg 4-8.

    Healthy Soils Are:  Well-structured.  NRCS Newsletter article #14

    http://www.ydae.purdue.edu/natural_resources/Soil,Health/Activities/SlakeTest,NRCS.pdf

    Soil Quality for Environmental Health, Slaking

    http://soilquality.org/indicators/slaking.html

     

     

    Well-structured soil on the left can resist crusting.

  3. Soil Temperatures, Accumulated GDD and Corn Emergence

    Author(s): Greg LaBarge, CPAg/CCA, Peter Thomison

    We have been tracking soil average 2 inch average bare soil temperatures since 4/1/18 from regional representative stations in the OARDC Weather System. The soil temperature information from 4/1 to 4/22 is shown in the chart below.

    We heard of some corn planting around April 12.  Corn typically requires 100 to 120 growing degree days (GDDs) to emerge (but emergence requirements can vary from 90 to 150 GDDs). GDD are based air temperatures, not on soil temperatures.

     

    To determine daily GDD accumulation, calculate the average daily air temperature (high + low)/2 and subtract the base temperature which is 50 degrees F for corn. If the daily low temperature is above 50 degrees, and the high is 86 or less, then this calculation is performed using actual temperatures, but if the low temperature is less than 50 degrees, use 50 degrees as the low in the formula. Similarly, if the high is above 86 degrees, use 86 degrees in the formula. The high cutoff temperature (86 degrees F) is used because growth rates of corn do not increase above 86 degrees F. Growth at the low temperature cutoff (50 degrees F) is already near zero, so it so it does not continue to slow as temperatures drop further.

     

    Accumulated GDDs from regional representative stations in the OARDC Weather System are shown in Table 1.

     

    Table 1. Accumulated GDD from April 12 to April 22 at select OARDC Weather stations.

     

    OARDC Station

    Accumulated GDDs since April 12

    Northwestern-Custer

    22

    Wooster

    45

    Western-Springfield

    41

    Piketon

    65

    If it takes a corn hybrid 110 GDDs to emerge, and daily high and low temperatures average 70 and 50 degrees following planting, 10 GDDs accumulate per day, and corn should emerge in about 11 days (110 GDDs to emerge/10 GDDs per day = 11 days). However, if daily high and low temperatures are cooler, averaging 60 and 45 degrees after planting, 5 GDDs accumulate per day, and it may take more than 3 weeks (110 GDDs to emerge/5 GDDs per day = 22 days) for corn to emerge. In past years, corn planted in mid to late April has taken as much as 3 to 4 weeks to emerge in many fields.

    Temperatures at or below 50 °F may also impact final plant stands, especially when there is protracted period of low temperatures following planting. When such conditions occur, stand loss is usually greater on heavier and poorly drained soils.

    Given the relationship between GDD accumulation and emergence, we should not be too surprised that it sometimes takes early planted corn up to 3 or more weeks to emerge. Seedling emergence is dependent on soil temperature and air temperature. Also, keep in mind that estimates of emergence based on GDDs are approximate and can be influenced by various factors including residue cover, tillage, planting depth, hybrid differences, and soil organic matter (soil "color") and moisture content.

  4. Some improvement for the next 2 weeks

    Author(s):

    Air and soil temperatures remain below normal across Ohio with most soil temperatures below the critical 50 degree level. There is a risk of some frost this Thursday morning and some frost and near freeze conditions this weekend especially north of I-70. This will keep pressure on soil temperatures warming too fast.

    The end of April will be not as cool or wet. We will see a round of on/off rain into early Wednesday especially the southeast half of Ohio. Rain totals this week will range from under 0.25 inches in northwest Ohio to 0.5 to 1.0 inches over the south and east sections of the state. Temperatures will average a few degrees below normal this week but nothing like it has been.

    The first week of May will bring some good news with above normal temperatures! It will start dry but rain is expected to return by around May 3.  Overall, May is shaping up to be closer to normal temperatures but wetter than normal rainfall.

    June is looking to be warmer than average with rainfall going from wetter to drier than normal during the month. July is shaping up to be hotter and drier than normal. August is shaping up to be warmer and wetter than normal.

    You can keep up-to-date on modified growing degree days from the NOAA Midwest Climate Center at : http://mrcc.isws.illinois.edu/cliwatch/mgdd/gdd_maps.html

    All areas of the corn and soybean belt are way below normal for growing degree days especially west of Ohio.

    The pictures below indicate the latest totals and departures from normal.

  5. Chance to view Ohio’s 2018 Conservation Tillage and Technology Conference video sessions

    Author(s): Sarah Noggle

    For those of you who did not attend the 2018 Conservation Tillage and Technology Conference in Ada, Ohio in March, or you want to learn from concurrent sessions you missed, here is another chance.  Sixty-six recorded video presentations are available at https://fabe.osu.edu/CTCon/ctc-2018-archive.  Topics from the conference included: regenerative agriculture, climate change, healthy soil, water quality, research reporting of data, cover crops, federal policy, and nutrient management.  Plan now to attend in 2019 on March 5-6.   

  6. Inversion and Drift Mitigation Webinars available

    Author(s): Cindy Folck, Amanda Bennett

    The recorded webinars from the Inversion and Drift Mitigation Workshop held in April are available online here.  

    The recordings include: 

    • Understanding Inversions and Weather Conditions by Aaron Wilson, Weather Specialist & Atmospheric Scientist, OSU Extension, Byrd Polar & Climate Research Center
    • Using Tools in the Ohio Sensitive Crop Registry by FieldWatch by Jared Shaffer, Plant Health Inspector, Ohio Department of Agriculture.

    Project funded by: The Ohio IPM Program and USDA-NIFA Project 20177000627174.

Crop Observation and Recommendation Network

C.O.R.N. Newsletter is a summary of crop observations, related information, and appropriate recommendations for Ohio crop producers and industry. C.O.R.N. Newsletter is produced by the Ohio State University Extension Agronomy Team, state specialists at The Ohio State University and the Ohio Agricultural Research and Development Center (OARDC). C.O.R.N. Newsletter questions are directed to Extension and OARDC state specialists and associates at Ohio State.

Contributors

Amanda Douridas, CCA (Educator, Agriculture and Natural Resources)
Anne Dorrance (State Specialist, Soybean Diseases)
Beth Scheckelhoff (Educator, Agriculture and Natural Resources)
Bruce Clevenger, CCA (Field Specialist, Farm Management)
Chris Zoller (Educator, Agriculture and Natural Resources)
Clifton Martin, CCA (Educator, Agriculture and Natural Resources)
Dean Kreager (Educator, Agriculture and Natural Resources)
Elizabeth Hawkins (Field Specialist, Agronomic Systems)
Garth Ruff (Educator, Agriculture and Natural Resources)
Greg LaBarge, CPAg/CCA (Field Specialist, Agronomic Systems)
Greg LaBarge, CPAg/CCA (Field Specialist, Agronomic Systems)
Lee Beers, CCA (Educator, Agriculture and Natural Resources)
Mark Badertscher (Educator, Agriculture and Natural Resources)
Peter Thomison (State Specialist, Corn Production)
Sam Custer (Educator, Agriculture and Natural Resources)
Sarah Noggle (Educator, Agriculture and Natural Resources)
Ted Wiseman (Educator, Agriculture and Natural Resources)

Disclaimer

The information presented here, along with any trade names used, is supplied with the understanding that no discrimination is intended and no endorsement is made by Ohio State University Extension is implied. Although every attempt is made to produce information that is complete, timely, and accurate, the pesticide user bears responsibility of consulting the pesticide label and adhering to those directions.

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