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Carryover injury from fomesafen herbicide if the herbicide was misapplied. Corn leaf veins would appear white while interveinal tissue remains green.1
Sulfur deficiency generally appears as a yellowing of young leaves and is sometimes confused with nitrogen (N) deficiency. Because S is not as easily translocated within the plant, younger leaves show the visual symptoms first.
The older leaves of the corn plant may turn pale or yellowish-green when the plant is deficient in N. The deficiency then starts to create a V-shape yellowing in the leaf, starting at the tip of the leaf.2
A Zn-deficient corn plant exhibits interveinal chlorosis on the upper leaves. The veins, midrib, and leaf margin remain green. As the deficiency intensifies, bands (or “stripes�?) develop on either side of the midrib and the leaves may turn almost white. Additionally, a Zn-deficient corn plant may be stunted causing shortened internodes on the stalk.
Soils that may have been saturated by heavy rains in the past year may cause restricted crop growth and nutrient uptake. Compaction layers form when heavy farm equipment passes over wet ground. These compaction layers can block root systems and limit nutrient availability. Wet soil conditions can also reduce soil oxygen levels, which can affect root growth and nutrient uptake. Continued crop growth through drier, sunnier weather may help some of these issues.
Results from tissue and soil testing can help determine if a deficiency is due to soil availability or plant uptake and metabolism. Plant tissue analysis, during the growing season, can provide S, Mg, and Zn levels in the plant at the time of sampling.3 Generally when testing S, Mg, and Zn levels, the corn ear leaf should be sampled at silking; however, analysis procedures may vary by lab.4 An early-season tissue analysis can be done after the seedling stage, but prior to tasseling.
When plants with a suspected nutrient deficiency are sampled, it is recommended that a sample of unaffected plants at a similar stage also be collected. Early-season testing results can be used to determine if a supplemental fertilizer should be applied. A tissue test, in combination with a soil test, may give answers as to why nutrient levels are high or low in a plant. Soil test results alone will be most useful for predicting nutrient needs for the following growing season, but may not give reliable results for S levels.
Plants can often outgrow symptoms. This is because soil warming encourages microbial activity and breakdown of organic material, which releases additional nutrients. Deeper root growth can also allow roots to reach water-soluble nutrients such as S and N that may have leached deeper into the soil with wet conditions.
A corn plant will transition from energy dependence on the seed to acquiring energy from photosynthesis between the V3 to V5 growth stage. The cosmetic appearance of plants during these stages is often variable and can be due to an environmental effect. A wait-and-see approach can be taken during the vegetative stages, and a tissue analysis may be conducted at silking stage if symptoms persist into the season. Correcting the problem for the current crop may not be feasible, but soil preparation for next season can include fertilizer applications based on soil test recommendations and compaction alleviation or prevention.
1Gower, S. 2006. Fomesafen carryover to corn. Michigan State University. Field Crop Advisory Team Alert.
2Fernandez, F. 2009. Identifying nutrient deficiencies in corn. University of Illinois. The Bulletin No.13 Article 6.
3Stevens, G. Integrated pest management: Crop nutrient deficiencies and toxicities. University of Missouri-Columbia. IPM1016.
4Thom, W. O. 2000. Sampling for corn plant tissue analysis. Iowa State University Extension. NCH-15.
Other sources used: Rehm, G. 2004. Striped corn: causes and corrections. University of Minnesota. Minnesota Crop News. June 17, 2004; Rehm, G. and Schmitt, M. 1989. Sulfur for Minnesota soils (FO-00794-GO). University of Minnesota; Rehm, G., Rosen, C, and Schmitt, M. 2002. Magnesium for crop production in Minnesota (FO-00725-GO). University of Minnesota; Rehm, G. and Schmitt, M. 2002. Zinc for crop production (FO-00720-GO). University of Minnesota.
Web sources verified 03/29/2017. 130411060201