Degree-days for Prediction of Western Bean Cutworm Flight in 2024

Degree-days for Prediction of Western Bean Cutworm Flight in 2024

The very first western bean cutworm (WBC) moths have been caught in the black light trap at Clay Center, Nebraska. However, WBC have not yet been reported from Mead, Concord or North Platte (see the Light Trap Data site). It is time to start thinking about scheduling for scouting for this important pest of corn and dry beans. WBC moths prefer to lay their eggs on corn plants when they are approaching tassel emergence, as the tassel is the preferred food source for newly hatched WBC larvae. A match between the flight of the moths and the late whorl to early tassel stage of corn can result in high levels of infestation.

Predicted Dates of WBC Flight for Nebraska in 2024

Overall, the estimated dates for WBC flights in 2024 are slightly earlier than those from 2022-2023. Earliest flights will be observed in eastern Nebraska, such as Lincoln and Grand Island, while the latest flights will be recorded in the Panhandle, such as Sidney and Alliance, Nebraska (Table 1).

Table 1. Predicted dates of WBC flight for select locations in Nebraska.
MunicipalityCoordinatesElev.5%10%25%50%75%90%95%
Alliance, NE 42.17 -102.93 4072 20-Jul 23-Jul 26-Jul 30-Jul 2-Aug 6-Aug 9-Aug
Ainsworth, NE 42.57 -99.83 2500 10-Jul 12-Jul 15-Jul 19-Jul 22-Jul 26-Jul 29-Jul
Arthur, NE 41.45 -101.72 3589 11-Jul 13-Jul 16-Jul 20-Jul 23-Jul 27-Jul 30-Jul
Clay Center, NE 40.52 -98.05 1788 1-Jul 3-Jul 6-Jul 9-Jul 13-Jul 17-Jul 19-Jul
Columbus, NE 41.46 -97.33 1450 30-Jun 2-Jul 5-Jul 9-Jul 12-Jul 16-Jul 19-Jul
Concord, NE 42.38 -96.97 1545 3-Jul 6-Jul 9-Jul 13-Jul 17-Jul 20-Jul 23-Jul
Gothenburg, NE 40.95 -100.20 2628 5-Jul 7-Jul 10-Jul 14-Jul 17-Jul 21-Jul 24-Jul
Grand Island, NE 40.96, -98.31 1843 28-Jun 30-Jun 4-Jul 7-Jul 11-Jul 15-Jul 17-Jul
Hayes Center, NE 40.55 -101.03 3064 7-Jul 9-Jul 12-Jul 16-Jul 19-Jul 23-Jul 26-Jul
Holdrege, NE 40.5 -99.37 2323 6-Jul 8-Jul 11-Jul 15-Jul 18-Jul 22-Jul 25-Jul
Imperial, NE 40.50, -101.65 3294 2-Jul 4-Jul 7-Jul 11-Jul 14-Jul 18-Jul 21-Jul
Kearney, NE 40.72 -99.02 2129 3-Jul 6-Jul 9-Jul 12-Jul 16-Jul 20-Jul 23-Jul
Lincoln, NE 40.84, -96.76 1170 24-Jun 26-Jun 29-Jun 3-Jul 7-Jul 10-Jul 13-Jul
North Platte, NE 41.08 -100.78 2841 7-Jul 9-Jul 13-Jul 16-Jul 20-Jul 23-Jul 26-Jul
Ogallala, NE 41.12 -101.72 3230 6-Jul 8-Jul 12-Jul 15-Jul 19-Jul 23-Jul 25-Jul
Scottsbluff, NE 41.88 -103.68 3934 10-Jul 12-Jul 15-Jul 19-Jul 23-Jul 26-Jul 29-Jul
Sidney, NE 41.22 -103.03 4331 11-Jul 13-Jul 17-Jul 20-Jul 24-Jul 28-Jul 30-Jul
York, NE 40.87 -97.63 1637 1-Jul 3-Jul 6-Jul 10-Jul 13-Jul 17-Jul 20-Jul

To produce the table above, recorded temperatures were taken from the High Plains Regional Climate Center (HPRCC) from March 1 to June 17. A 10-year (2014-2023) average was used in order to predict the average temperature for dates after June 17.

Another option for seeing moth flight predictions in your area is to use UNL’s AgriTools mobile app for Apple or Android, which will provide predictions similar to the table above by pulling temperature data from weather stations around your location.

Introduction to Insect Degree-day Models

The importance of knowing when an insect pest will cause damage in a field is essential to producers and crop consultants when making management decisions. Since insect development is greatly affected by temperature, the timing of insect emergence can be estimated accurately by using a combination of calendar dates and assessment of temperature variations from year to year.

The use of a degree-day model can help provide producers with accurate data. Degree-days measure the amount of heat between upper and lower developmental thresholds to which an insect has been exposed. A model for the western bean cutworm (WBC) has been developed through the collaboration of entomologists from the University of Minnesota and the University of Nebraska.

Each degree-day model is different, but most models will subtract the lower threshold from the average temperature for each day. For example, in the model developed for WBC, if a certain day had a low of 55°F and a high of 65°F, and the model has a lower threshold of 38°F and an upper threshold of 75°F, then the degree-days would be calculated as:

[(65+55)/2]-38

[120/2]-38 = 22°F degree-days

Note: If the average temperature is less than the lower threshold (38°F), then you should use the lower threshold as the average temperature. If the average temperature is greater than the upper threshold (75°F), then you should use the upper threshold as the average temperature.

Western Bean Cutworm Degree-day Model

Entomologists from the University of Nebraska-Lincoln (Tom Hunt and Robert Wright), and the University of Minnesota (Roger Moon, Bill Hutchison, and Anthony Hanson) developed the most recent degree-day model. The lower threshold is 38°F, while the upper threshold is 75°F beginning on March 1. Once 2,577 degree-days Fahrenheit is reached, 25% of the WBC flight occurs and scouting of corn fields should begin. (Pheromone trapping in dry bean fields should begin the last week of June before any WBC have emerged.)

If an insecticide application is warranted, it should be made 10-21 days after peak flight in dry bean and when 95% of plants have tasseled in corn. For more information, see NebGuide G2013 by Seymour et al. 2010.

Table 2. Relationship between WBC flight and accumulated degree-days.
°Days F (±95% Confidence Interval)% WBC Flight
2,377 (1,843 - 3,066) 5
2,456 (2,147 - 2,809) 10
2,577 (2,416 - 2,749) 25
2,704 (2,577 - 2,838) 50
2,838 (2,660 - 3,027) 75
2,977 (2,603 - 3,046) 90
3,077 (2,385 - 3,968) 95

Scouting and Management of Western Bean Cutworm

WBC eggs can be found on the upper surfaces of corn leaves and the lower surfaces of dry bean leaves. Eggs are found in masses ranging from 5-200, with an average of 50-85. When first laid, the eggs will be white and gradually darken during the five- to seven-day development (Figure 1). Freshly hatched larvae will first eat the eggshells before consuming the host plant (Figure 2 and 3). Older larvae can be identified by two dark-colored rectangular spots directly behind their head (Figure 3). Adult moths are identifiable by a white band on the anterior margin on the forewing followed by a white circle halfway down the wing and a white crescent located two-thirds down the wing (Figure 4). WBC moths are about three-fourths of an inch long by 1.5 inches wide.

Figure 1. Western bean cutworm egg mass. (Photo by Jeff Cluever)
Figure 2. Western bean cutworm egg mass with first instar larvae. (Photo by Andrea Rilakovic)
Figure 3. Western bean cutworm larva. (Photo by Silvana Paula-Moraes)
Figure 4. Western bean cutworm adult moth. (Photo by Julie Peterson)

It is more challenging to scout for WBC in dry bean fields due to dense and robust bean canopy.  However, pheromone traps can be used to provide an estimate of a possible infestation and should be installed prior to the predicted 5% flight date. If fewer than 700 moths are caught up to peak, there is low risk; if more than 700 but fewer than 1,000 moths are caught, then there is moderate risk; and if there are more than 1,000 moths caught, then the risk is high.

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