Optimizing Overhead Irrigation Droplet Size for Six Mississippi Soils

Optimizing Overhead Irrigation Droplet Size for Six Mississippi Soils

Optimizing overhead irrigation practices will ensure that water loss is minimized, and each unit of water is used most effectively by the crop. In order to optimize overhead irrigation setup, a study was conducted over two years in Mississippi to quantify the optimal overhead irrigation duration and...

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Bibliographic Details
Published in:Agronomy (Basel) Vol. 10; no. 4; p. 574
Main Authors: Ferguson, J. Connor, Krutz, L. Jason, Calhoun, Justin S., Gholson, Drew M., Merritt, Luke H., Wesley, Michael T., Broster, Kayla L., Treadway, Zachary R.
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-04-2020
Subjects:
Agricultural production
Agriculture
Containers
Crop production
Crop yield
Crops
droplet size spectrum
Droplets
Efficiency
Infiltration
Irrigation
Irrigation efficiency
Irrigation practices
Irrigation water
Nozzles
Optimization
Organic matter
Organic soils
Pesticides
Physical properties
Rainfall
Simulation
Soil analysis
Soil erosion
Soil profiles
Soil properties
Soil testing
Soil texture
Soil types
Soils
Sprays
Testing laboratories
Texture
Water infiltration
Water loss
Water use
Water use efficiency
United States > US
Mississippi
Mississippi River
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Summary:Optimizing overhead irrigation practices will ensure that water loss is minimized, and each unit of water is used most effectively by the crop. In order to optimize overhead irrigation setup, a study was conducted over two years in Mississippi to quantify the optimal overhead irrigation duration and intensity for six soil types commonly found in row-crop production regions in the state. Each soil type was transferred to containers and measured for total water infiltration and water infiltration over time using a two-nozzle rainfall simulator in a track sprayer. The rainfall simulator was calibrated to apply 2.1 mm of water per minute. The rainfall simulator ran on a 2.4 m track for 90 s, with 3.2 mm total water applied during that time. After the 90 s overhead irrigation event, each container was undisturbed for 150 s and assessed for irrigation penetration through the soil profile. Commercially available irrigation nozzles were measured for droplet size spectrum. Results showed that across soil type, organic matter was the primary factor affecting water infiltration through the profile, followed by soil texture. Irrigation nozzle volumetric median droplet sizes ranged from 327 µm to 904 µm. The results will improve overhead irrigation setup in Mississippi, improving irrigation water use efficiency and reducing losses from soil erosion over the application of water and reduced crop yield.
ISSN:2073-4395
2073-4395
DOI:10.3390/agronomy10040574