2.10.9: Placement of Soil Water Sensors

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The above methods of soil water measurement require that representative sites be selected for sampling. This means that sampling must consider the variability in soils, the variability of water applications, and the variability of plant populations within the irrigated area. The microclimate around the area to be measured should also be considered. This is especially important in landscape applications where buildings and streets can greatly affect the environment surrounding the irrigated plants.

Soil water measurements must be taken at depths that represent the plant root zone. Estimates of soil water content secured with the heel of your boot usually are inadequate to describe what is really happening within the plant's root system. In Chapter 6, root zone depths for various crops will be presented. Installation of soil water sensors should be done with great care, since a good installation is required in order to obtain high-quality data.

One of the frustrations of measuring soil water is the large number of samples that are required before you feel comfortable with how well the measurements represent the soil water conditions in the irrigated area. Because of natural variability of soil properties and the variability in depth of rainfall and irrigation applications within the irrigated area, considerable variability in measured soil water can be expected. Another problem is the number of locations that must be monitored to truly represent the plant root zone. A minimum of two soil depths should be measured, and often three or four are required to properly represent root zone soil water conditions. One approach to reduce the uncertainty in soil water data is to focus more on the trends over time rather than the magnitude of the measurement. If possible, determine the FC from the sensor data after it is installed (looking at the trend after a large wetting event which saturates the soil profile), and track the amount of depletion below FC (i.e., calculate SWD) over time.

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