Tag Archives: Emergence

After the Flood: How much damage? What to Do?

Although we are currently drying out after the heavy rains over the weekend, I thought it would be a good idea to review the effects of flooding on soybean.  Usually, widespread flooding is not a major issue for us due to the sandy nature of our soils and/or well-drained fields.  Still, it can and has happened.

During the week ending on June 12, some parts of Virginia received 6 to 10 inches of rainfall (see map below).  Plus, more may be on the way. Rainfall 061213

This heavy rainfall has resulted in saturated soils and in some cases, flooding.  This field is a Soybean Research Verification Field in Dinwiddie County that I’ve been scouting.  The photo was taken after a hard rain on Friday, June 7.Flooding Soybean Dinwiddie 2013

It’s difficult to know the long-term effect of flooding on soybean fields.  Research is limited, but we do know that the fate of flooded fields will largely depend on 1) the development stage during which the flood took place; 2) the duration of the flood; 3) the temperature during and right after the flood; and 4) the drying rate after the flood.

Basically a flooded field depletes the roots of oxygen (O2), causing photosynthesis to slow.  After several days without O2, the plant may turn yellow, grown very slowly, and possibly die.  Other indirect effects of flooding can include reduced nitrogen-fixing bacteria (but they will recover), nutrient imbalances, and increased disease pressure.

Effects on Germination & Emergence.  The most damaging effects of flooding on un-emerged soybean occur when the duration of the flood is greater than 24 hours and/or when the soil temperature is low.  In controlled research conducted during the late 1990’s, researchers examined the effect of flood duration, soil temperature, and time after seed imbibition that the flood occurred.  They found that saturated conditions decreased germination by 15 to 43 percentage points when averaged over temperatures of 59O or 77O F (germination was 62% in the non-flooded control, averaged over temperature treatments).  When flooding lasted only 1 to 12 hours, germination was only decreased by an average of 15 percentage points, regardless of when the seed began imbibing water.  Even after 48 hours of saturated conditions, germination was only reduced by 20 percentage points if the flooding occurred one day after the seed imbibed water.  But, if the flooding occurred 2 or 3 days after the seed imbibed water, then the germination was lowered 33 or 43 percentage points, respectively.  Therefore, the farther along the seed was in the germination process, the more susceptible they were to flood damage.  Lower temperatures during the germination process increased the damage.  At 59OF, germination was lowered by 21 to 25 percentage points, regardless of the duration of the flood.  But at 77OF, germination was only lowered by this amount if the flood lasted 48 hours.  The researchers suggested that damage to the seed under brief flooding was primarily physical (e.g., seed membrane damage), but damage with longer flood duration was physiological (e.g., ethanol toxicity, O2 deprivation, CO­2 build up).

Flooding can also result in soil crusting.  This will be worse in tilled fields that are low in organic matter and surface residue.  Unless the crust is broken with a rotary hoe or similar implement, the emerging seedling, already stressed by the flood, will have an even more difficult time emerging and growing.

There is also an increased chance of seedling disease, but this is less of a problem at this time of the year with warm soil temperatures.  Poor stands will be the biggest issue.  To determine whether or not re-planting will be beneficial, refer to Virginia Soybean Update Vol. 13, No. 3 (June 2012).

Flooding After Emergence.  Soybean can generally tolerate up to 2 days of flooding.  But if the saturated soil conditions persist for more than 2 days, significant yield reductions may occur.  The amount of yield reduction will vary with development stage, duration of the flood, the type of flood (stream overflow vs. low land depressional), temperature during the flood, the drying rate after the flood, and the overall environmental conditions after the flood.

In general, the following comments can be made.  Flooding in the reproductive stages causes more damage than in the vegetative stages.  Yield is reduced more with longer flooding duration and with a slower drying rate of the field (e.g., a well-drained sandy soil will recover faster than a poorly-drained or heavier textured soil).  Higher temperatures after the flood will lead to greater yield losses.  This is because the recovering plant will deplete its stored energy at a faster rate.  In addition, high soil temperatures will result in greater microbial respiration, which lead to greater depletion of oxygen.  The best conditions for a recovering soybean crop are cool, cloudy days and cool, clear nights.

In a Arkansas study conducted on two poorly drained soils with slow permeability (Sharkey clay and Crowley silt loam), researchers found that yield decreased by 1.8 and 2.3 bushels per acre per day of flooding on the Sharkey clay when soybean were flooded from 2 to 14 days at the V4 stage (4 trifoliate leaves on the main stem) and R2 (full flower) stages, respectively.  On the Crowley silt loam soil, yield was reduced 0.8 and 1.5 bushels per day of flooding at V4 and R2, respectively.  It’s worth noting that this research did not have an un-flooded control treatment; therefore, the 2-day period of flooding was considered the control.  This research clearly showed that duration of the flood greatly impacts yield.  In addition, flooding during reproductive stages caused more yield loss that if the flooding occurred at vegetative stage.  Eight varieties were tested, but variety did not affect the flooding response.  Other researchers have however indicated that certain varieties exhibit greater flooding tolerance.

Another study in Louisiana evaluated 7 days of waterlogging on V2, V3, V7, R1, R3, R5, R6, and R6.3 stage soybean under greenhouse conditions. The V stages represent the number of trifoliate leaves on the main stem and the R stages represent beginning flower, beginning pod, beginning seed, full seed, and the temporal midpoint of seed filing.  In summary, the early vegetative stage (V2) and the early reproductive stages (R1, R3, and R5) were most sensitive to waterlogging.Saturated soybean

 

Although some research has been conducted, estimating the yield loss due to flooding is nearly impossible because we don’t know what the conditions will be like afterwards.  The best gauge may be ones past experience with fields that have flooded.

Fortunately, some of these experiences have been documented.  An example is research conducted in Ohio in 1998, where researchers monitored several fields that flooded during that year.  They reported a 20% reduction in soybean yield in one field and a complete loss in another field that was flooded for 3 days during the V2-V3 stage.  The field with the complete loss was due to thick sediment coating the plants and not allowing any recovery.  However, flooding for 3 days in two other fields caused no yield loss and flooding actually increased yield in a fifth field.  In the field where yield was increased, sediments covered the plants but a light rain soon after the flooding washed the sediment off.  In addition, greater residual soil moisture associated with the flooded area when a late-season drought occurred was probably responsible for the greater yield.  After 6 days of flooding, yield losses ranged from 0% at two sites to about 60% at a third site and over 90% at another site.  At one of the sites with no yield loss, the subsoil had a high sand content, which enable the root zone to quickly return to aerated conditions.

In another study, researchers found that flood irrigation for greater than 2 days reduced soybean yield by 20% as compared to a 1-day flood treatment.

What to Do After the Flood.  While it may seem that there is little to do to help a flooded crop, it is very important that we minimize any other stress on the crop that can prevent recovery.  First, try to stay off of the field.  Wet fields compact easily.  Compaction will further stress the crop and slow its recovery.  Make sure that the field is dry enough before taking equipment back on it.

Evaluate the stand.  If a stand reduction occurred, determine if it’s worthwhile to replant.  Remember that after mid-June, every day delay in planting will cost you about ½ of a bushel in yield.  The plants that remain are still higher yielding than seed that can now be planted, even if the stand has been substantially reduced.

Stress such as herbicide injury can slow the crop down further.  Still, weeds need controlling.  But you may want to select herbicides (usually as tank-mix partners to glyphosate) that don’t cause a significant amount of burning.

Cultivation is an option to conventionally tilled fields to help aerate the soil.  However, cultivating a wet soil can do more damage than good by causing additional compaction, which in turn would further stress the crop.

You may also want to dig a few roots and inspect for adequate nodulation.  Make sure the nodules are pink.  I see little that can be done, but knowing that the nodules are still working may give you peace of mind.  And while you’re doing that, split some stems and roots to check for any disease.  If suspected, send in to one of our Plant Disease Clinics to be further evaluated.

Finally, some will want to apply some type of foliar fertilizer to the crop to “kick-start” it back to health.  But, I see little advantage of this.  Remember that the real problem is lack of O2 to the roots and CO2 buildup in the soil; only after the roots begin to receive O2 will the recovery process start.

Hopefully you haven’t experienced severe flooding (> 24 hours).  But if so, be patient and evaluate the field.  Then make good decisions on how to handle it.

 

 

Cool Soils Should Alter Your Planting Plans

It goes without saying that every year is different and this winter/spring has been wet and cold. I think that most of us have assumed that the soil temperatures are much below normal; therefore, holding off a few days with planting may be a good idea.  According to 2013 and five-year historical soil temperature records at Orange and Suffolk (from the USDA-NRCS Soil Climate Analysis Network weather stations), soil temperatures have been fluctuating quite a bit.Virginia Soil Temps 2013

After early-April soil temperatures proved to be much colder than normal, a week or two of warm weather put us back on track with average.  Then, temperatures dropped off again.  Fortunately, the last two weeks of cool weather have not lowered the soil temperatures all that much.

Although our soils have warmed substantially since early April, the temperatures are still less than optimum for soybean germination and emergence.  Ideally, I like to see temperatures hold steady at 65 to 70O or above.  The ideal temperature for soybean germination is 77O and the optimum range is 68 to 86O.  The maximum is 94O, where germination can be inhibited.  However, we can’t always wait for perfect temperatures if we are to get all of our soybeans planted on time.

Still, planting soybean in cool (<65O) will lead to delayed emergence and increased chance of seedling disease that can reduce stands, weaken emerged plants, and inhibit early-season growth.  For a more detailed description of fungal seedling disease in soybean, refer to an article I wrote last May on the subject and can be found in my Virginia Soybean Update blog.

I stress that the greater time required for emergence, the greater probability that the seed will become infected with soil-borne disease.  If you are planting into cool soils, I strongly suggest using fungicide-treated seed as an insurance against seedling disease. These treatments will protect the seed and seedling if emergence is delayed.

But, seed treatments should not be a substitute for other practices that encourage rapid seedling emergence.  Here is my checklist for insuring a good stand free of seedling disease:

  • Know the germination and vigor of your seed; adjust the seeding rate accordingly.
  • Insure good soil-to-seed contact by properly setting your planter to cut through the residue and penetrate to the proper depth.
  • Plant soybean seed ¾ to 1 inch deep into good soil moisture.
  • Consider fungicide seed treatments if planting into cool soils.

Insure Rapid Seedling Emergence and Survival

Once the seed is in the ground with good soil-to-seed contact (insuring a good environment for germination), we must then turn our attention to getting the growing plant out of the ground as quickly as possible and insuring that it survives.  The longer the seed takes to germinate and emerge, the greater likelihood of poor stands and unhealthy plants.

Soil Moisture and Seedbed Condition.  Always try to plant into moist soils.  However, I recognize that this is easier said than done, especially when several hundred acres of soybean needs to be planted and it’s getting closer and closer to wheat harvest or you need to side-dress the corn, or many other things need doing.  Still, seed are expensive and replanting is even more expensive.

If the soil is completely dry, then the seed will usually wait on moisture.  Unfortunately, during dry times, the field is rarely completely dry.  If there is enough moisture to swell the seed but not get the seedling out of the ground, then we have a problem.  Seed need to imbibe over half of their weight in water to germinate.  The critical seed moisture content for germination is 20%.  Germination is not affected if the seed has imbibed water for 6 hours (seed is swollen, but seed coat not broken), then it dehydrates to 10% moisture.  If seed has imbibed water for 12-24 hours (seed coat is broken, no radical), then germination may be reduced 35-40%.  If the radical has emerged and seed drops to 10% moisture, few if any seedlings will survive.

Surface soil compaction will physically hinder emergence and also result in less soil moisture because of less pore space.  Row spacing will affect seedling emergence under crusted or compacted soil conditions because seed are closer together within the row; therefore, will exert more upward force, per foot of row, to emerge.

Soil Temperature.  The ideal temperature for soybean germination is 77OF and the optimum range is 68 to 86OF.  The maximum is 94OF, where temperature will actually inhibit germination.  Planting early (mid-April to mid-May) may delay emergence due to cool soils.  Planting in July increases risk of high soil temperatures, but soil moisture during this time of year is usually the bigger problem.  I did see high temperature inhibition in some of our double-crop plantings in 2010.  Regardless, if the soil temperature is not in the optimum range, emergence will be delayed.  With this delay comes a greater likelihood of the seedling being attacked by disease or insects.

Planting Depth.  Soybean seed depth should be between ¾ to 1¼ inches.  If topsoil moisture is lacking, use the deeper placement, but never plant deeper than 1½ inches.  If topsoil is adequate shallower seed placement may speed up emergence, but probably won’t make much difference under warm soil conditions.   Just make sure that the seed is in contact with moist soil.  Placement depth is controlled by the gauge wheels.  Ideally, these should be adjacent to the disk opener.  If controlled by the seed firming/closing wheel, then uniformity of seed depth could be erratic.  The deeper you plant, the longer it takes for the seedling to emerge.  The seedling physically has further to go to emerge, plus the soil may be cooler at deeper depths.  Germination and emergence rate is controlled by temperature.  So, when soils are warm, deeper planting depth has less detrimental effect on emergence.  If soils are hot, deeper placement may actually be beneficial.  Finally, uniform time of emergence of seedlings should be a goal even though soybean compensate well.

Protecting the Seed and Seedling.  Certain environments such as cold soils, non-rotated land, poor quality seed, or a field history of insect pests or disease favor specific pests.  Again, the greater time required for emergence, the greater probability that the seed will become infected with soil-borne disease.  Therefore, rapid emergence is the best defense against seedling disease.  No-tillage/high residues, early planting, planting into cold soils, and deep seed placement are all factors that may delay emergence; therefore, your management will need to be adjusted when one or more of these conditions are present.  Seed treatments will protect the seed and seedling if emergence is delayed, but should only be used if other methods to decrease emergence time have been exhausted.

To review, here’s a checklist for rapid seedling emergence:

  • Know the germination and vigor of your seed.
  • Insure good soil-to-seed contact
  • Plant soybeans ¾ to 1 ½ inches deep and into sufficient soil moisture.
  • Plant into warm soils (68 to 86OF).
  • Consider fungicide seed treatments if planting early into cool soils.