Crop water use, consumptive use and evapotranspiration (ET) are all terms used interchangeably to describe the water consumed by a crop. Evapotranspiration (ET) is used to describe the movement of water through evaporation (E) from the soil and plant surfaces and transpiration (T) through the plant. Transpiration is the movement of water from the soil into plant roots, through plant stems and leaves, and back out into the atmosphere. Transpiration is an important concept because yield is related to the amount of water a plant transpires. Understanding corn water use and the factors that affect it can help guide more efficient irrigation applications.
Corn water use fluctuates throughout the season depending on weather conditions and crop growth stage (Figure 1).
Figure 1. Example of long-term daily average (A) and individual year (B) corn water use with select growth stages. Source: Kranz, W.L. et al. 2008. Irrigation management for corn. NebGuide G1850. University of Nebraska-Lincoln Extension.
High yielding corn requires approximately 22 to 30 inches (560 to 760 mm) of water per year depending on planting date, planting density, maturity group, location, and weather conditions.2 Corn requires the most water during the early reproductive growth stages (Table 1), which are also the most sensitive stages to water stress. Substantial reductions in yield can occur if corn does not receive enough water to meet ET demands during this critical water use period.
|Table 1. Example of crop water use (ET) by growth stage for 113-day maturity corn.
||Average water use rate inches (mm)/day
||Total water use during growth stage inches (mm)
|Blister kernel (R3)
|Beginning dent (R4)
|Full dent (R5)
|Full dent (R5)
|Table modified from Kranz, W.L. et al. 2008. Irrigation management for corn. NebGuide G1850. University of Nebraska-Lincoln Extension.
Early Growth Stages
Corn uses very little water during the seedling stage. If early season precipitation and stored soil moisture are adequate for seedling emergence and early plant development, irrigation is not recommended immediately following planting. Without the plant canopy to shade the soil surface, much of the irrigation could be lost to evaporation. However, there are two scenarios where overhead sprinkler irrigation is recommended just after a corn crop is seeded.
- If after planting the surface soil moisture has dried to the point where there is not enough moisture to meet the germinating seed requirement for uniform germination and emergence, then an irrigation application or two of 0.5 to 1.0 inches (12.5 to 25 mm) per application, depending on soil type, is recommended. This is to ensure uniform emergence and reduce the occurrence of late emerging seedlings or skips in the stand due to seeds in dry soil, delayed germination, or failure to germinate at all.
- If pre-emerge herbicides are applied just before or after planting, a light irrigation of 0.5 to 1.0 inches (12.5 to 25 mm) is often used to incorporate these herbicides into the top two inches (50 mm) of the soil profile to position the herbicide in the soil zone of germinating weed seeds.
Producers should rely on stored soil moisture and natural precipitation as much as possible during the early growth stages as an early irrigation can also cool the soil and delay seed germination and early growth.
The vegetative stages of corn are often considered the least sensitive stages to water stress yield loss. If irrigation supplies are limited, the vegetative stages may provide an opportunity to conserve irrigation for the reproductive stages where it will have the most impact on yield potential (Figure 2).
Figure 2. Corn plants at six leaf vegetative growth stage under heat and moisture stress.
Early Reproductive Stages
Corn water use peaks during the early reproductive stages. Water stress should be avoided during tasseling, silking, and pollination. Water stress during silking can have the greatest impact on yield potential due to desiccation of the silks and pollen grains, which can result in poor pollination.1 Corn water demands often exceed precipitation amounts during these critical growth stages (Table 2). It is important to plan ahead by knowing the capacity of the irrigation system to ensure that adequate water is available to the crop through these growth stages.
|Table 2. Effects of irrigation on corn yields, Scandia Experiment Field, 1980-1991.
|Time of Irrigation
||1991 Irrigation Dates
|Tassel and 1 Week After Tassel
|Table modified from Corn Production Handbook C-560 2007, Kansas State University Extension.
*1991 demonstrates a year of severe drought prior to pollination.
Dough through Dent Stages
Corn water use rates steadily decrease from the dough stage through maturity due to a lower evaporative demand (shorter days, lower temperatures, lower solar radiation), a loss of transpiring leaf area as lower leaves begin to die, and changes in plant physiology.1 Corn continues to require roughly 30% of its seasonal water requirement at the beginning of the dough stage (Table 3). For optimal grain development and maximum yield potential, corn requires water right up to physiological maturity. Water stress during the dough through dent stages can accelerate maturity, prohibiting kernels from reaching their full potential size and weight (poor kernel test weight).3
|Table 3. Example of water requirements for corn during the late reproductive stages through maturity.
||Approximate days to maturity
||Water use to maturity inches (mm)
|1/4 milk line
|1/2 milk line (full dent)
|3/4 milk line
|Table modified from Yonts, C.D. et al. 2008. Predicting the last irrigation of the season. NebGuide G1871. University of Nebraska-Lincoln Extension.
Water is no longer needed for kernel growth after physiological maturity (black layer) and no yield benefits can be achieved with additional irrigation. Allowing soils to dry at maturity is a good strategy for avoiding compaction that can be caused by harvesting machinery on wet soils.
Water Use Efficiency
Water use efficiency (WUE) is defined as the amount of grain produced per unit of water used by a crop. The concept of WUE has been around for a long time but research is ongoing to help determine what can be done to grow more crop with less water. Enhancing WUE at the canopy level can be achieved by adopting practices that reduce the soil water evaporation component and divert more water into transpiration which can be achieved through crop residue management, mulching, row spacing, genetic response, and irrigation system efficiency.4
Residue Management and Tillage System Response
The soil water evaporation component of ET can be reduced with conservation tillage and strip tillage which can be increased with surface crop residue. Adding crop residue to the soil surface has shown benefits in decreasing soil water evaporation and increasing WUE in semi-arid regions.4 Tillage increases the exposed surface area of the soil which increases evaporation and runoff, destroys crop residue that can catch rain and snow, and may reduce water infiltration rate because of compaction that can be created during the tillage process. Surface residue also helps increase infiltration rates by limiting the amount of surface sealing (crusting) created by rainfall and irrigation droplets. When a droplet hits a bare soil surface there is a physical disintegration of soil aggregates and their compaction, caused by the impact of raindrops, which can cause soil surface sealing and result in poor water intake rates. The residue is a physical barrier that does not allow the droplet to impact the soil surface. Surface residue also helps reduce runoff by creating obstructions that limit water movement and allow more time for water to percolate into the soil profile.
Row Spacing Response
Narrow rows can help reduce the time the soil is not covered and may increase WUE by decreasing soil evaporation. This may be a potential water management tool to increase WUE especially for water limited environments or under rainfed environments with variable rainfall during the growing season. Evaporation can be suppressed in irrigated fields by increasing planting density to encourage rapid ground cover. In general, more of a yield response to narrow rows is expected to occur in northern production states, likely due to their shorter growing seasons. There is an advantage to narrow rows for yield increase in a high-yield environment and no advantage in the mid- to low-yield environments.5
The concept of WUE has been proposed in plant breeding to help identify water use efficient genotypes under changing climate regimes, heat and water-deficit stress, and interactions among them. It has been demonstrated that apparent photosynthesis and transpiration under water-deficit conditions were related to WUE and could be used as tools to assess comparisons in genetic material. The resilience of genetic material to stress, e.g., temperature or water, will provide the newer genetic material with greater WUE.4
The type of irrigation and irrigation system design can drastically affect the WUE of a corn crop. No irrigation system is 100% efficient but converting a flood or furrow irrigation system to overhead sprinkler irrigation or even realizing more efficiency by converting to a subsurface drip system, can drastically increase irrigation efficiency.
Furrow or flood (surface) type irrigation may only be 50% efficient when you consider the potential for run-off and application rate variability. Excessively long irrigation runs result in water being lost to the crop by deep percolation on the upstream end of the field by the time the downstream end is adequately irrigated. And by the time the downstream end is adequately irrigated there is the potential for excessive runoff. WUE is negatively affected by both potential water losses to the crop.
Overhead sprinkler irrigation WUE can be drastically affected by the height of the irrigation nozzle above the canopy and the water droplet size created by the nozzle package. The wind velocity along with small irrigation droplet size can reduce the irrigation efficiency by increased evaporation before the water droplet hits the soil surface. Another area of poor WUE is the area watered by the end gun on many systems. Many systems have had the end gun removed because the WUE for the area irrigated by the end gun is often the least efficient area irrigated under the overhead irrigation system. Remote system monitoring can now be used to check on a system’s function and even start or stop a system which can have a positively effect on the WUE.
Subsurface drip-irrigation (SDI) is a way of irrigating crops through plastic tubes placed under the soil surface. These systems reduce the soil water evaporation, from between the plant rows, early in the season and limits almost all the evaporation component from the canopy. Using an SDI system can help provide high WUE and potential savings of 25-50% compared to flood irrigation. Using SDI also has a positive effect on the environment through reduced nitrate leakage in the lower soil layers, unlike other irrigation systems especially flood or furrow irrigation systems. One of the reasons that SDI is not used on more acres is the initial cost of installation. The investment to install this type of the system can range from $2,000 to $4,000 per acre.6
When considering an irrigation system for corn production any system or nozzle package that can shift more of the water use from evaporation to transpiration can positively affect the WUE.2
Cover Crop Response
Cover crops have the potential to reduce soil erosion and compaction, increase water holding capacity, soil organic matter, and suppress weeds which can all have a positive effect on the WUE of a corn crop. Different cover crop species and different cover crop planting dates may have specific effects on cropping systems especially in semi-arid areas where the moisture available to grow a crop has a substantial effect on corn yield potential. Timing of cover crop termination is key to avoiding excessive cover crop growth, water use, and nitrogen immobilization, and consequently potentially reducing corn grain yield.7
WUE has increased over time because the grain yields have increased while water use has remained relatively constant.
1 Kranz, W., Irmak, S., van Donk, S., Yonts, D. and Martin, D. Irrigation Management for Corn, NebGuide G1850. https://water.unl.edu/article/agricultural-irrigation/irrigation-management-publications-nebraska-extension
2 Schneekloth, J. and Andales, A. 2017. Seasonal Water Needs and Opportunities for Limited Irrigation for Colorado Crops – 4.718 https://extension.colostate.edu/topic-areas/agriculture/
3 Lamm, F.R. and Abou Kheira, A.A. 2009. Corn irrigation macromanagement at the seasonal boundaries – initiating and terminating the irrigation season. Proceedings of the 2009 CPIC. Colby, Kansas, Feb 24-25.
4 Hatfield, J. L., Dold, C., 2019. Water-Use Efficiency: Advances and challenges in a changing climate. National Laboratory for Agriculture and the Environment, Agricultural Research Service, United States Department of Agriculture, Ames, IA. https://www.frontiersin.org/articles/10.3389/fpls.2019.00103/full
5 Presley, D., Shoup, D., Holman, J. and Schlege, A. Efficient crop water use in Kansas. Kansas State
6 Petkovski , M. 2020.The advantages of subsurface drip irrigation in corn production. AgFuse.
7 Tonon Rosa, A., Elmore, R., Creech, C. and Werle. R. 2019. Impact of cover crop management on rainfed corn production in western Nebraska. https://cropwatch.unl.edu/2019/cover-crop-impact-rainfed-corn
Web sources verified 06/21/21.
Performance may vary from location to location and from year to year, as local growing, soil and weather conditions may vary. Growers should evaluate data from multiple locations and years whenever possible and should consider the impacts of these conditions on the grower’s fields.
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