Determining the Last Irrigation for Corn, Soybeans and Sorghum

Determining the Last Irrigation for Corn, Soybeans and Sorghum

August 17, 2007

Too Early Can Reduce Yields; Too Late Can Increase Costs

Table 1. Normal water requirements for corn, grain sorghum and soybeans between various stages of growth and maturity in Nebraska.

Growth stage

Days
to maturity

Water use
to maturity
(in inches)


Corn

Blister (R2)

45

10.5

Dough (R4)

34

7.5

Full dent (R5)

24

5.0

 milk line

19

3.75

 milk line

13

2.25

 milk line

7

1.0

Physiological maturity (R6)

0

0.0

 

 

 

Grain Sorghum

Half bloom (Stage 6)

34

9.0

Soft dough �(Stage 7)

23

5.0

Hard dough (Stage 8)

12

2.0

Physiological maturity (Stage 9)

0

0.0

 

 

 

Soybeans

Full pod development (R4)

37

9.0

Beginning seed fill (R5)

29

6.5

Full seed fill (R6)

18

3.5

Leaves begin to yellow (R6.5)

10

1.9

Beginning Maturity (R7)

0

0.0

 

The 2007 growing season has resulted in above normal growing degree days and crops are reaching maturity earlier than in recent years. That also means that the last irrigation of the season will occur earlier. In order to reduce irrigation costs and conserve water, start planning for when you want to apply that last irrigation of the season.

Because of the difference in application amount, furrow irrigators need to decide soon while pivot irrigators can delay the decision and take advantage of any rainfall. With the range in maturities grown across the state, the best way to determine if more irrigation is needed is to go through a step-by-step procedure.

Step 1.

Determine the crop stage of growth for each field. Develop a field average growth stage by evaluating the crop at four to five locations just as you do when scouting for insects. Table 1 gives some targets to look for. Depending on the maturity range and planting date, there likely will be a range in maturities across a county.

Step 2.

The toughest part is estimating how much water remains in the soil. An excellent discussion of how to use the hand-feel method is presented in an USDA-NRCS publication, Estimating Soil Moisture, available at local Natural Resources Conservation Service offices. In fields where soil water sensors are installed, they should be used to determine how much water is left in the soil.

Using the hand-feel method can require a lot of practice to get it right. Begin by squeezing the soil as if making a fist; if a wet outline of the ball of soil remains on your hand, the soil is very near field capacity or 100% of available soil water content. As the soil dries, the wet outline disappears and the soil will crumble when pressure is applied to the ball of soil with your thumb. At 50% available water content, sandy soils tend to form a ball, but crumble when your hand pressure is released. Silt loams will tend to stick together after pressure is released. Clay loams will stick together and form a short ribbon when the soil is squeezed between your thumb and forefinger. The NRCS publication does a good job of showing how the soil looks at different soil water contents.

Step 3.

Multiply the active root zone depth in feet by the total soil available water capacity and the current percent soil water content. For example, a sandy loam soil, 4 feet deep can hold up to 5.6 inches of plant available water (4 x 1.4 inches per foot). If the average current percent soil water content is 75%, then 4.2 inches of plant available water remains in the soil (0.75 x 5.6 inches).

Step 4.

Subtract the minimum balance from the current available water content to get the remaining useable water in the soil. Crops need adequate water to maturity to ensure that the grain is filled to full size. To prevent yield losses, the soil water content should be kept above the 40% of available soil water level as the crop nears maturity. So, the minimum balance for a sandy loam soil would be 2.2 inches (0.4 x 5.6 inches). The remaining useable water for this sandy loam soil is 2.0 inches (4.2 - 2.2 inches).

Step 5.

Determine the amount of water needed to carry the crop through to maturity. Table 1 summarizes the estimated crop water requirements for corn, grain sorghum and soybean. Each year and variety will be slightly different so field scouting is an important part of making a final decision. For example, if corn is near the full dent stage in much of your area, the crop water requirement to reach maturity is around 5 inches and typically requires about 24 days.

Step 6.

Finally, subtract the depth of water needed to take the crop to maturity (Step 5) from the remaining useable water (Step 4). If the result is positive, no further irrigation is needed. If not, keep track of crop water use rates and effective rainfall. Irrigate only if rainfall does not meet crop needs. In the example above, an additional 3 inches of water would be needed to take the crop to maturity without significant stress (2.0 - 5.0 = -3.0 inches).

The last irrigation decision is always an important one. By following these steps and determining how much water the crop still needs, you can minimize the amount of irrigation water applied to the field, save on energy costs, and have good yields.

C. Dean Yonts
Extension Irrigation Specialist
Panhandle REC, Scottsbluff
Bill Kranz
Extension Irrigation Specialist
Northeast REC, Norfolk

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