Watermark Sensors to Assess Soil Moisture and Schedule Irrigation

Published on by in Technology

Watermark Sensors to Assess Soil Moisture and Schedule Irrigation

It is often said here in the Mid-South that we are always 10days from a drought! However, with the widespread and abundant rainfall received through mid-June in Mississippi, irrigation was not really a primary concern until we recently reboundedback tomore typical summertime weather. With irrigation season ramping up, Mississippi State University Extension Service has lots of expertise and programs available to assist with your needs. One tool that we are using to better assess soil moisture and schedule appropriate irrigation is Watermark™ sensors.

The Watermark™ sensors are tension based sensors measuring field water holding capacity. The normal range of operation of the Watermark ™ sensors is from 0 to 200 cb, with 0 cb signifying a soil saturated with water, and 200 cb representing dangerously dry soil. We believe an appropriate irrigation trigger for our Mississippi soils should generally be from 80 cb to 100 cb, for our row crops based on ours' and other field experience and research. Other factors, such as irrigation capacity or type, as well as crop growth stage may affect appropriate moisture level for scheduling irrigation. For example, we would suggest using a trigger point approximately 20 cb lower for older center pivots with limited capacity, compared to other irrigation systems.

Proper irrigation timing involves evaluation of the sensor values throughout the rooting zone. The rooting zone is defined as depth at which roots are utilizing water. If you have sensors placed 6, 12, and 24 inchesdeep within the soil profile, the initial readings immediately after installation may read much like this: 5, 3, and 0 cb. After a week of becoming acclimated to the soil conditions with no rainfall or irrigation events, the sensors may read 50, 40, and 0 cb. These fluctuating readings confirm the plants roots are utilizing water present at least 12 inchesdeep, but are not presently utilizing water beyond that depth. Although this effective rooting zone may change with time, in this example the entire rooting zone is in the top 12 inches of soil. Knowing that the rooting zone consists of the top 12 inches(100%) of the soil profile with a sensor at 6″ (50%) and one at 12″ (50%), calculating the irrigation initiation trigger is quite easy. As the effective rooting zone moves deeper, we must use an appropriate factor depending on the spacing between sensors at different depths.

Following are three different examples for your review.

In the first example, the rooting zone is only 12 inches,so calculations are only based on the 6 and 12" sensors. Each sensor reading is multiplied by 50% and the sum total isan average moisture value of 45 cb.

Details can be seen here

Media

Taxonomy