2.10.3: Neutron Scattering

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An accurate method for measuring soil water is the neutron scattering or attenuation technique, which uses an instrument called a neutron probe. With this method, a radioactive source is lowered into an access tube installed vertically into the soil (Figure 2.15). The source is lowered to the desired depth of measurement and emits neutrons traveling at high speed. The speed of the neutrons is attenuated or slowed by hydrogen ions present in soil water. The rate of attenuation is dependent on the amount of water present. A detector, located near the source, counts the number of slow-moving neutrons over a short count period, 30 seconds to 2 minutes. There is a good correlation between the count of slow-moving neutrons and θ_v.

An advantage of this method is the size of the soil volume sensed by the instrument. In effect, the probe samples a sphere with a diameter of 6 to 10 in, depending on soil water content. Neutron probes are also more accurate (within 1%) than most other soil water sensors. Disadvantages of the method include: (1) high initial cost, (2) a license is required to operate an instrument that is radioactive, (3) a calibration curve (Figure 2.16) must be developed for a given access tube material (usually aluminum, steel or polyvinyl chloride plastic) and for the soil of interest, (4) measurements within the top 6 to 8 in of soil are not reliable and require a separate calibration, and (5) measurements can only be made where the access tubes have been installed. The last item can be an advantage if repeated measurements at the same location in the field are desired. Neutron probes are often used in irrigation research.

Figure 2.15. Neutron attenuation method for measuring volumetric water content in a soil profile.

Neutron probe and access tube showing spherical volume measured in wet and dry soils (greater volume in dry)

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