Tag Archives: soybean

Soybean Sprouting in the Pods/Pod Splitting

Posted on September 20, 2018 by David Holshouser

We are seeing immature soybean once again sprouting in the pods in Suffolk and Gloucester County, and I heard of this happening in other states. This seems to occur every 3-6 years somewhere. Although I don’t have a great explanation for why this occurs, it usually happens when there are good growing conditions early followed by 2-4 weeks of drought stress during pod formation, and then excellent conditions return for seed fill. Typically, it happens in big-canopied soybean (lots of leaf area) with lots of yield potential, but not enough pods (or big enough pods) to fulfill that potential. I think that the seeds enlarge so much that the pod splits.

Keep in mind that I’m talking about immature seeds and pods. This can also occur after the crop matures (R7 to R8) when we get excessive rainfall after the seed in question has dried down. But, I have not seen that yet this year.

There is little that you can do about it. Those sprouted seed will usually dry up on the plant and be blown out the back of the combine.

Although there has to be some yield loss, I’ve not seen it to be very great. And, I suspect that if you did not notice the sprouted seed, you probably would not know that you had a loss.

For more information, see previous blogs on this subject.

Wet Conditions May Lead to Soybean Seed Sprouting

The Good and Bad of a Wet September

Soybean Considerations Following Hurricanes

Posted on September 20, 2018 by David Holshouser

Although Virginia escaped the disaster caused by Hurricane Florence for the most part, Dr. Rachel Vann, N.C. State Soybean Extension Specialist, has written an excellent article, Soybean Considerations Following Hurricane Florence, on steps to evaluate flooded soybean.

I suggest saving for future reference and hope that we won’t need it.

Finishing Out the Soybean Crop – What do we need for Good Yields?

Posted on August 30, 2018 by David Holshouser

In general, we’ve had a good, but not great year for soybean in Virginia. Although many areas were hit with a 3 to 4 week dry spell during July, August rains kept us in the game. However, we did not see the ample rains or cool temperatures that we experienced in August of 2017, which resulting in record yields. Below is a summary of August rainfall and temperature anomalies for the U.S.

As you’ll notice, we had about average or slightly below average precipitation and average to slightly above average temperatures for most of Virginia’s soybean growing areas.

So, I do not suspect that our yields will be as good as last year. Still, our earlier-maturing varieties planted in April or May should yield quite respectably considering that most have made over 50% of their yield – they have reached the R6 stage (see photo below). Yield of our later-maturing varieties, planted in May and early June, and our double-crop plantings are not quite there yet – much of our yield is yet to be determined – R5 soybean have only made roughly 25% of their yield at that time.

So, what do we need for good yields? Rain is obvious. Full-canopied plants with adequate soil moisture will draw about 0.25 inches of water/day from the soil. But, we also need cool temperatures – soybean do not generally like 90+ degree days, especially when forming seed.

Below is the 10 day rainfall and temperature forecast for the U.S., and it does not necessarily look good for us. Note that the rainfall is predicted accumulation and the temperature map shows anomaly. Although we should get some rain this weekend only (more in northern parts), temperatures are supposed to be above average. But, forecasts are only forecasts. The weather does change. I hope we will get the needed rainfall that they are predicting this weekend. But a big ridge appears to be setting up over the Mid-Atlantic states for next week. This usually means warm weather and only at the edges of ridges do we normally see rainfall – note the heavy rainfall predicted from Nebraska through Michigan.

I don’t mean to discourage, just to inform. We still have decent soil moisture, at least in the subsoil. With rain this weekend, we should get through next week without too much harm to the crop.

Our double-crop soybean (assuming late maturity group 4’s and group 5’s planted in late June to July) are just now in the R5 stage – it usually takes 80 to 100 days from planting to reach R6, depending on maturity and planting date. So some timely September rains will usually result in good double-crop soybean.

When will our yield be “made”? Below is table showing the number of days to soybean physiological maturity (R7; 95% of yield has made). When can we expect to be harvesting our soybean? Full maturity is reached about 2 weeks after R7 and harvest can proceed after the soybean have dried down to a harvestable moisture, usually within a week after R8.

Walk Your Fields

Posted on July 5, 2018 by David Holshouser

For greater soybean yields, one of the best things that you can do is walk your fields. Many problems reveal themselves during the summer. Actions taken or not taken can be very noticeable. By walking fields, we can see what’s working and what’s not working. Certain problems can be solved, some cannot. For those that cannot be solved this year, we can do better next season by understanding why we have the problem. Therefore, a review of how to diagnose your crop will likely beneficial.

A few years ago, I published “Troubleshooting The Soybean Crop“. Although a little dated, most of the information is still good. This publication will guide you through how to go about diagnosing problems, includes a vegetative- and reproductive-stage outline with lots of photos, and also includes a sample crop scouting and diagnostic form. You can download a view a PDF copy, or contact me – I still have a few hard copies left. By following some general guidelines, one can become quite good at diagnosing problems. Below is a summary.

First, document everything! Memories tend to fade. We often forget or overlook details. You can document by taken notes (many phone apps or iPad/tablets work well for this). Make a recording. Take pictures – this is especially useful when you need help – and send those photos to others.

PRELIMINARY FACT FINDING. You can obtain plenty of information before you even get to the field. Although I call this preliminary (as if you’ve not seen the problem), you may need to go back to the office to refresh your memory of what you did. Information that can be acquired beforehand or back in the office includes:

Cropping History
Equipment
Soil Information
Weather
Pest Management Information
Tillage and Other Cultural Practices

THE FIELD VISIT

Take all materials and equipment needed (e.g., phones, paper, shovel, plastic bags, soil probes, etc.)
Windshield/Whole Field Investigation
Above-Ground Inspection
Take Appropriate Plant or Soil Samples
Equipment Check
Interaction with Others
Document Everything!

ANALYSIS OF DATA AND FINDINGS

Patterns
Look-Alike Symptoms
Interacting Factors/More Than One Problem

DRAWING A CONCLUSION. Review the facts and data. Eliminate unlikely causes. Validate likely causes. You may be able to drawn a conclusion in the field, but lab analysis may be needed.

FOLLOW UP. Revisit the field. If you took corrective action, did it work? Why or why not?

This is a very rough outline of the guide. Again, if you want a hard copy of Troubleshooting The Soybean Crop, contact me.

Yellow soybean leaves may be due to manganese (Mn) deficiency

Posted on June 21, 2018 by David Holshouser

Manganese (Mn) deficiencies are common in Virginia soybean and are starting to appear in numerous fields. These deficiencies are not necessarily due to low Mn levels in the soil, but are more likely related to high soil pH levels, as its availability decreases with increasing soil pH.

Although soils with a pH of 6.2 or lower can occasional show Mn deficiencies, it is most likely to appear when pH levels reach 6.5 or above. Furthermore, Mn deficiencies are more common on our sandier soils because pH changes more rapidly and these soils typically have a lower concentration of the nutrient.

The deficiency will appear as interveinal chlorosis, usually on the younger leaves first since Mn is not a mobile nutrient. MnDeficiency0721101059 This may distinguish Mn deficiency from magnesium (Mg) deficiency. Magnesium deficiency symptoms will usually appear on the lower leaves while the upper leaves remain green. Still, I’ve seen Mn deficiency on the lower to middle leaves. This usually happens when the field has not been checked in a while and the observer missed the symptoms when they were on the younger leaves. Cyst nematode on roots

Other problems can cause look-alike symptoms similar to Mn deficiencies. In particular, interveinal yellowing is a common symptom of soybean cyst or other nematode damage. Therefore, it may be prudent to further investigate the problem, especially the root system.

Use the following guidelines for Mn applications:

Scout your fields. Mn deficiencies may or may not materialize. The only sure way to determine a deficiency is to observe the deficiency symptoms through visual observation or tissue tests. The characteristic visual symptom is yellowing between the veins on the new leaves. Mn is an immobile nutrient. Therefore, it will not move out of older leaves to the new leaves. Symptoms will appear when the plant can no longer extract sufficient amounts of the nutrient from the soil.

Take a tissue sample. If Mn deficiencies are suspected due to high pH and/or a field history of Mn deficiencies, but no symptoms have yet appeared, you should consider taking a tissue sample. Tissue samples can reveal deficiencies before symptoms appear (hidden hunger). We suggest a tissue test if lime, lime stabilized biosolids, or an ash product was recently applied.

Manganese application. To overcome a deficiency, apply ¾ lb. chelated Mn (elemental basis) or 1 lb. inorganic Mn (elemental basis) per acre to foliage upon appearance of symptoms and prior to flowering. More than one application may be required to correct a severe deficiency.

Don’t use low rates to correct a deficiency. Note that many Mn products recommend applying lower rates of Mn. However, the label usually states that these are maintenance rates. Once a deficiency occurs, these lower rates will not correct the deficiency and the rates stated above will be needed.

Split Mn application on deficiency-prone soils. An alternate method of application can be used before a deficiency is evident on soils that commonly show a deficiency, especially on soils that have a high pH (above 6.8 or so). A lower rate (~ ½ of that listed above) can be combined with another scheduled application, such as a postemergence herbicide or insecticide. This may be a sufficient rate to prevent a deficiency from occurring. But, continue to scout the field and take future corrective measures if visual deficiencies appear. If a visual symptom appears, you need to use the full rate. I will remind you that this is a preventative treatment. A deficiency may not occur. Furthermore, these are only maintenance rates and another application will likely be needed if the field is truly deficient.

Use EDTA chelated Mn formulations when mixing with glyphosate. Be reminded that some Mn formulations in combination with glyphosate herbicide (Roundup, Touchdown, many generics, etc.) will result in reduced weed control of certain weeds. Other herbicides have not shown to interact. If including Mn with glyphosate, use the EDTA chelated formulation as it has shown not to interact.

Don’t spray if you don’t need it. In addition to the cost, Mn can be toxic to soybean. Spraying greater than recommended rates or spraying as a preventative spray when soil pH is relatively low (5.7-5.9) could lead to toxicity problems

Wet Soils, Poor Stands – Do I Replant?

Posted on May 31, 2018 by David Holshouser

The decision of whether or not to replant arises every year; however, the wet soil conditions seem to have worsened the problem this year. There of course will be areas that the decision is easy – flooded areas resulting in almost no stand. But, what about fields that just are not living up to your expectations? I’ve seen and heard many reports of stands being reduced 25 to 50% of what was expected (keep in mind that our expectations are sometimes too high).

First, I must mention that final average stands of 60,000 to 80,000 plants/acre rarely profit from replanting. Only when you get below 50,000 can it be economically justified. I refer you to the seeding rate data shown. Note that yield does not fall off until seeding rates fall below 90 to 120 thousand seed/acre (76 to 107 seed/acre on productive soils). Stands generally averaged 75%; so, this is equal to 65 to 90 thousand plants/acre. Once you add in the cost and of and time required to replant, it’s not usually worth it – unless the stand less than this.

Steps to Estimate the Profitability of Replanting Soybean

Posted on May 31, 2018 by David Holshouser

Determining whether or not to replant is hard. To ease the pain, I’ve summarized some relatively simple steps to help in your decision. One should incorporate 2- to 3-foot gaps into your decision to improve the estimation of yield loss.

Determine the cause of the poor stand. Was the poor stand the result of poor seed quality, cold wet soils, hot dry soils, planting too deep or shallow, soil crusting, herbicide injury, insect or slug feeding, poor soil to seed contact, or disease infection? Determine if the cause can be corrected to avoid a similar situation. If slug or insect feeding or disease is the cause, then you might expect poor stands again.
Estimate the stand and percent stand loss due to gaps. Pace off the sections of row 20 paces long in at least 6 areas of the field. Determine (in number of paces) the total length of row lost to 2- to 3-foot gaps. For drilled soybean, this can be interpreted at 2- to 3-foot diameter gaps. Then determine the percent of row lost to gaps. In addition, count and determine average number of plants per foot in sections of row not reduced by gaps. The simplest method is to count the number of healthy plants (capable of recovery) in a length of row equaling 1/1000 of an acre. For instance:

36-inch rows = 14.5 feet
30-inch rows = 17.5 feet
20-inch rows = 26 feet
15-inch rows = 35 feet
7.5-inch rows = 70 feet

Then, just multiply your counts by 1,000 to get plants per acre.

Or, use the Tables 1 or 2 to determine remaining plant population. The “hula hoop” method (Table 2) is valuable with drilled soybean or when rows cannot be distinguished. This involves placing a circular measuring device such as a hula-hoop on the ground and counting the plants contained within.

Table 1. Plant populations of different row spacing with different plant counts per foot.
Plants/ foot	Row Spacing
Plants/ foot	36	30	24	20	15	7.5
	Plant Population (1,000’s/acre)
1	15	17	22	26	35	70
2	29	35	44	52	70	140
3	44	52	65	78	105	210
4	58	70	87	105	139	278
5	73	87	109	131	174	—
6	87	105	131	157	209	—
7	102	122	152	183	244	—

Table 2. Hula-hoop method for determining drilled soybean populations.
No. ofPlants	Inside Diameter of Hula Hoop
No. ofPlants	30”	32”	34”	36”	38”
	Plant Population (1,000’s/acre)^a
6	53	47	41	37	33
10	89	78	69	62	55
14	124	109	97	86	77
18	160	140	124	111	100
22	196	172	152	136	122
26	231	203	179	160	144
^aPlants/acre = no. plants ¸ (3.14 x r2 ¸ 43,560 ft2) where r = radius of hula hoop in feet.

Estimate the yield of the poor stand. Use Tables 3 and 4 to determine percent of yield potential for full-season and double-crop plantings, respectively. Note that Table 3 is data from Illinois from the 1980’s. In my opinion, the remaining plant population numbers are too high. Although I have not conducted full-season plant population studies that have included gaps, I suggest that you change those numbers to 60, 90, and 120 (based on Virginia data). Multiply this percentage by the expected yield. This is the yield to expect from the deficient stand.

Table 3. Yield response (% of maximum) of full-season soybeans to deficit stands^a.
% Stand lost to gaps^b	Remaining Plant Pop (1,000’s/A)
% Stand lost to gaps^b	70	105	140
0	95	97	100
10	93	96	98
20	91	93	96
30	88	90	93
40	83	86	89
50	78	81	84
60	73	75	78
^aSource: Pepper and Wilmot. Managing Deficit Stands. 1991. Illinois Cooperative Extension Cir. 1317.^bGaps of 12 inches or more; 30-inch rows

Note that these data are from Virginia.

Table 13.4. Yield response (% of maximum) of double-crop soybeans to deficit stands^a.
% Standlost to gaps^b	Remaining Plant Pop (1,000’s/A)
% Standlost to gaps^b	100	140	180	220
0	80	88	95	100
20	71	79	86	91
40	61	69	76	81
60	48	57	64	69
^aSource: 2001-2004 experiments, Suffolk, VA.^bGaps of 3 feet; 15-inch rows; MG 4 variety

Estimate the yield from replanting. After mid-June, decrease the expected yields an additional half of a bushel per acre per day delay in planting. This is the yield to expect from delayed planting.
Determine the gain or loss from replanting. Subtract the expected yield of the poor stand (step 3) from the yield expected from delayed planting. This is the gain or loss in bu/A from replanting. Multiply this number by the expected price ($/bu), using future prices, to obtain gain or loss in $/A.
Estimate the cost of replanting. Include per acre cost of tillage, herbicide, fuel, seed, and labor.
Determine profitability of replanting. Subtract your cost of replanting from your estimated gain from replanting.

Flooded Soybeans – How Much Damage? What to do?

Posted on May 24, 2018 by David Holshouser

Rainfall across the state resulted in in saturated soils and sometimes flooded soybeans or fields to be planted in soybean. Although fields are drying out, more rain is expected this weekend.

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.

For more detailed information, see a blog post that I wrote in 2013 at the Virginia Soybean Update site.

In short, here are a few pointers for flooded fields. If soybean have not yet been planted:

I don’t recommend tillage to dry the soil out for continuous no-till fields. Tillage will destroy the soil structure that you’ve built since tillage was stopped. The field is probably draining better than it ever was; tillage will just cause water to stand longer in the future.
Bradyrhizobia japonicum, the nitrogen-fixing bacteria that helps provide soybean with that nutrient, is harmed by lack of oxygen caused by the flood. Although the bacteria will recover, it may be prudent to add inoculant to the seed in areas that were flooded.

For flooded fields that have been planted:

1. Minimize any addition stress by staying out of the field. Do not try to plant or replant too soon. More damage can be done to the soil and more yield can be lost from planting into we soils than from planting too late.
2. If soybean have not yet emerged and crusting evident, light tillage with a rotary hoe will help emergence.
3. 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.
4. 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.
5. Finally, some will want to apply some type of foliar fertilizer to the crop to “kick-start” it back to health. 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.

Be Careful Planting Into Wet Fields – We Still Have Time to Maximize Soybean Yield

Posted on May 24, 2018 by David Holshouser

Recent heavy rains have led to temporary flooding of numerous soybean fields throughout Virginia and put us behind with soybean planting . Only 26% of the crop was planted as of last week. And it looks as if we will have another bout of rain this weekend.

Although you will be tempted to get back into these fields as soon as possible, I caution you to hold off until the entire field dries to a point where you will not damage the soil, especially around the seed. Planting into wet soils can compact the soil around the seed, making rapid seedling growth difficult. For continuous no-till fields, you can also cause some long-term compaction that will not be easily removed without tillage. I usually advise to wait another half or full day before you think you can get back into the field. In the long run, it will likely pay off.

When should we get into a big hurry to plant? Planting date research indicates that we usually don’t see a rapid decline in yield until mid-June. Below is some Virginia research to verify this.

Although the below multi-state data is double-crop soybean, it also illustrates the point well.So, you are likely to lower your yield much more by planting too wet than delaying the planting (or re-planting) until the last week of May or the first week of June. Still, only you know your operation. If you still have hundreds, or maybe even thousand acres to go, you may not want to wait too late.

2018 Weed Management Field Day

Posted on May 24, 2018 by Michael Flessner

Mark your calendar and plan to attend!

June 19th, 2018

8:30 to 11:30am

Highlights:

• View over 100 herbicide plots
• The latest corn and soybean herbicides
• Nozzle selection
• Herbicide resistant Palmer amaranth and common ragweed control options
• Integrated weed management tactics
• Free coffee and doughnuts!