2.10.5: Capacitance Probes

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Similar to TDR, capacitance probes also take advantage of the correlation between ε_a and θ_v. However, instead of measuring ε_a directly with travel time, it is estimated indirectly by quantifying capacitance and frequency, which is why these sensors are known as capacitance probes (or frequency domain reflectometry). This method uses the soil as a dielectric and measures the capacitance of the soil (Evett, 2007). The capacitance circuit is pulsed with highfrequency radio waves. A natural resonant frequency is established which is dependent on the capacitance. The measured frequency is used to calculate the capacitance, which is used to determine the ε_a, which is correlated to θ_v. Capacitance probes can be an easy-to-use option for monitoring trends in θ_v; however, for accurate determination of the magnitude of θ_v, capacitance probes are highly dependent on a calibration for the specific soil in which it is installed.

There are two forms of capacitance probes. One form has two or three electrodes which are inserted directly into the soil. The probe can be permanently installed at the desired depth in the soil profile, or it can be a portable device with the electrodes inserted at the soil surface. The measurement volume is dependent on the length and spacing of the electrodes. The second form requires an access tube (Rudnick et al., 2016), similar to neutron scattering. This allows soil water to be determined at multiple depths in the soil profile; however, the sensing volume is much smaller since the sensor is not in direct contact with the soil. Several types of capacitance probes are produced by industry for irrigation management.

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