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| Potassium Deficiency in Soybean: Diagnosing Hidden Hunger and Protecting Yield |
| Insect Update |
| LSU AgCenter Specialists |
David Moseley and Leandro Vieira, LSU AgCenter Scientists; and Carrie Ortel, Virginia Tech Extension Soybean Agronomist
Potassium (K) deficiency in soybean can be both visible and hidden, and both forms can reduce yield. Severe deficiency is often easy to identify, appearing as yellowing along the leaf edges. However, a more subtle form (hidden hunger) occurs when K levels are insufficient to maximize yield but do not produce obvious visual symptoms. This is especially common in fields with low to medium soil-test K levels, making it critical for producers to proactively manage K fertility rather than relying solely on visual cues.
The first priority in K management is ensuring an adequate supply of soil-K concentration. Soil testing using Mehlich-3 extraction provides a reliable baseline for determining K status and guiding pre-season fertilizer recommendations, with application rates varying based on soil-test K levels.
Table 1. Interpretation of Mehlich-3 soil-test for potassium (K) (Vieira et al., 2025)
| Soil Texture | Level | Concentration (ppm) | Recommendation (lbs K2O/A) |
| All | Very low | <50 | 120 |
| All | Low | 51-100 | 100 |
| All | Medium | 101-150 | 60 |
| All | Optimum | 151-250 | 0 |
| All | Above optimum | >250 | 0 |
Monitoring plant K status during the growing season is essential, especially when soil-K concentration is low or medium. Tissue sampling should begin at the R1 (beginning bloom) growth stage to ensure that the crop has sufficient K to support reproductive development. For a representative sample, at least 18 random trifoliate leaves should be collected across the field. It is critical that the correct plant tissue is sampled to ensure consistency with interpretation guidelines. Specifically, the third fully open trifoliate from the top of the plant should be collected, excluding the petiole. Consistent sampling methodology allows for reliable comparison to established sufficiency thresholds.
Figure 1. The third open trifoliate from the top of the plant should be collected without the petiole for tissue samples.
Leaf-K concentrations should be evaluated relative to established critical concentration curves, which describe how plant K requirements change as the crop develops. These curves indicate that K concentration naturally declines as the plant progresses beyond R1. If measured leaf-K levels fall below the expected range for a given growth stage, a corrective in-season K application may be warranted. The potential to recover yield depends on both the severity of the deficiency and the timing of the application relative to R1. Research indicates that visible K deficiency can be corrected within 20 days of R1 and hidden hunger can be corrected within 44 days of R1.
Figure 2. The critical concentration curve for potassium in soybean from the R1 growth stage to 70 days after R1. The percent relative yield for each curve (95%, 85%, and 75%) assume no potassium fertilizer is applied in-season to correct potassium deficiency (Ortel, 2025).
For cases of hidden K deficiency, a general recommendation is to apply approximately 60 pounds of K₂O per acre. However, ongoing research by the Science for Success team (a group of soybean agronomists) aims to refine these recommendations by better defining optimal application rates based on the degree of deficiency and growth stage at application. These efforts will help improve the precision of in-season K management decisions in soybean production systems.
More information can be read in this Science for Success Potassium Management in Soybeans article.
Ortel, C. (2025). Potassium management in soybeans. Science for Success.
Parvej, P. and Moseley, D. (2024). Tissue testing helps in determining hidden hunger potassium deficiency in soybean. LSU AgCenter Louisiana Crops Newsletter 14(4).
Vieira, L.O., Tubana, B., Padgett, G.B, Moseley, D., Gravois, K., Levy, R.J, & Kerns, S.P. (2025). Fertilizer recommendations for field crops in Louisiana: N-P-K-S. LSU AgCenter. P4004
James Villegas and Dawson Kerns, LSU AgCenter Field Crop Entomologists
Field Crop Scout School will be held on June 4 in Winnsboro and June 12 in Alexandria. These training sessions will cover a range of topics, including insect, disease, and weed identification, general IPM principles, and plant growth and development. The program is designed for scouts at all levels of experience. Extension agents, producers, consultants, and other stakeholders are welcome to take part in the event. Lunch will be provided.
Please register for this free event if you plan to attend. Registration link is available here: 2026 Field Crop Scout School
Recent pheromone trap data indicates increasing corn earworm (aka bollworm) moth activity across several monitoring locations in Louisiana with notable “spikes” that can signal increased egg-laying risk in susceptible crops. These moth flights are a timely reminder to intensify scouting especially in fields entering or currently in flowering/reproductive stages, particularly soybean. While moth trap captures are useful indicators of flight activity, they do not represent economic thresholds. Field-based sampling is critical for treatment decisions.
More information about corn earworm traps capture: Corn Earworm Moth Activity Update
The Rice Delphacid (RD) is an invasive planthopper that feeds on rice and other grasses. It was first recorded in Texas in 2015 and has since become a recurring rice pest in Texas rice belt. In Louisiana, RD was detected in July 2025 (first record in >70 years), with initial finds in Tensas Parish and later detections on ratoon rice across the state. This factsheet summarizes key identification and biology, typical damage symptoms, and guidance for scouting.
Rice Delphacid factsheet can be accessed here: Rice Delphacid Factsheet
The pasture mealybug (Heliococcus summervillei) is an invasive insect pest associated with pasture dieback and damage to a range of grasses. In Louisiana, it was confirmed in 2025 from sugarcane fields in Vermilion and Iberia Parishes. Its ability to infest multiple grass hosts means producers and consultants should watch for symptoms in pastures, hayfields, turf, and sugarcane-adjacent fields. This factsheet summarizes key identification and biology, typical damage symptoms, and practical guidance for scouting.
Pasture mealybug factsheet can be accessed here: Pasture Mealybug Factsheet
| Specialty | Crop Responsibilities | Name | Phone |
| Soybeans | Agronomic | David Moseley | 318-473-6520 |
| Wheat | Agronomic | Boyd Padgett | 318-614-4354 |
| Pathology | Cotton, grain sorghum, soybeans | Boyd Padgett | 318-614-4354 |
| Pathology | Corn, cotton, grain sorghum, soybeans, wheat | Trey Price | 318-235-9805 |
| Entomology | Corn, cotton, grain sorghum, soybeans, wheat | James Villegas |
225-266-3805 |
| Weed science | Corn, cotton, grain sorghum, soybeans | Stephen Ippolito | 318-473-6520 |
| Nematodes | Agronomic | Tristan Watson | 225-578-1464 |
| Irrigation | Corn, cotton, grain sorghum, soybeans | Stacia Davis Conger | 904-891-1103 |
| Ag economics | Cotton, feed grains, soybeans | Kurt Guidry | 225-578-3282 |
| Soil fertility | Corn, cotton, grain sorghum, soybeans | Leandro Vieira | 225-578-2110 |
| Corn, Cotton, and Grain Sorghum | Agronomic |
Shelly Pate Kerns | 318-435-2908 |
| Entomology | Field Crops | Dawson Kerns | 806-474-7220 |
The LSU Agricultural Center is committed to providing equal opportunity for all qualified persons in admission to, participation in, or employment in the programs and activities which the AgCenter operates without regard to race, creed, color, marital status, sexual orientation, religion, sex, national origin, age, mental or physical disability, or veteran’s status. Find detailed information at www.lsuagcenter.com/eeo.
Should you need any ADA accommodations, please contact David Moseley at 479-466-0457 no later the 10 days prior to the event.
