In situ measurement of soil moisture: a comparison of techniques

Walker, Jeffrey P.; Willgoose, Garry R.; Kalma, Jetse D.

Title: In situ measurement of soil moisture: a comparison of techniques
Creator: Walker, Jeffrey P.; Willgoose, Garry R.; Kalma, Jetse D.
Relation: Journal of Hydrology Vol. 293, Issue 1-4, p. 85-99
Publisher Link: http://dx.doi.org/10.1016/j.jhydrol.2004.01.008
Publisher: Elsevier BV
Resource Type: journal article
Date: 2004
Description: A number of automated techniques for point measurement of soil moisture content have been developed to an operational level over the past few decades. While each of those techniques have been individually evaluated by the thermogravimetric (oven drying and weighing) method, typically under laboratory conditions, there have been few studies which have made a direct comparison between the various techniques, particularly under field conditions. This paper makes an inter-comparison of the Virrib®, Campbell Scientific CS615 reflectometer, Soil Moisture Equipment Corporation TRASE® buriable- and connector-type time domain reflectometry (TDR) soil moisture sensors, and a comparison of the connector-type TDR sensor with thermogravimetric measurements for data collected during a 2-year field study. Both qualitative and quantitative comparisons between the techniques are made, and comparisons made with results from a simple water balance 'bucket' model and a Richards equation based model. It was found that the connector-type TDR sensors produced soil moisture measurements within the ±2.5% v/v accuracy specification of the manufacturer as compared to thermogravimetric data when using the manufacturer's calibration relationship. However, comparisons with the water balance model showed that Virrib and buriable-type TDR sensors yielded soil moisture changes that exceeded rainfall amounts during infiltration events. It was also found that the CS615 reflectometer yielded physically impossible soil moisture measurements (greater than the soil porosity) during periods of saturation. Moreover, the buriable-type TDR measurements of soil moisture content were systematically less than the Virrib measurements by approximately 10% v/v. In addition to the good agreement with thermogravimetric measurements, the connector-type TDR soil moisture measurements yielded the best agreement with Richards equation based model predictions of soil moisture content, with Virrib sensors yielding a poor agreement in the deeper layers. This study suggests that connector-type TDR sensors give the most accurate measurements of soil moisture content out of the sensor types tested.
Subject: soil moisture; in situ measurement; techniques; comparison
Identifier: http://hdl.handle.net/1959.13/34024
Identifier: uon:3481
Identifier: ISSN:0022-1694
Language: eng
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