Field Measurement of Solute Travel Times Using Time Domain Reflectometry

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Field Measurement of Solute Travel Times Using Time Domain Reflectometry

R. G. Kachanoski^*, E. Pringle and A. Ward

Dep. of Land Resource Science, Univ. of Guelph, Guelph, ON., Canada N1G 2W1. Contribution from the Dep. of Land Resource Science, Univ. of Guelph, and the Univ. of Waterloo Center for Groundwater Research, Waterloo, ON, Canada

ABSTRACT

A limiting step in our understanding of solute transport throughunsaturated field soils is the lack of experimental data. Fieldsolute transport characteristics such as the travel-time densityfunctions, F_L(T), for different soil depths are often very difficultand time-consuming to measure. The objective of this study wasto develop a method to measure F_L(T) for a conserving traceradded as a pulse under conditions of constant surface waterflux density. The method uses vertically installed time domainreflectometry (TDR) probes. At constant soil volumetric watercontent, ${vartheta}$ , the TDR estimate of bulk electrical conductivity,EC_E, is related to the average pore water concentration of anadded solute tracer, which in turn is related to the total specificmass (g m^-2) of the tracer between the TDR probes. The changein EC*_E with time is shown to be linearly related to the massflux of the solute past the ends of the TDR transmission rods.Solute mass flux out of a laboratory column was very similarto that measured using the TDR method. Excellent agreement wasalso obtained between solute-mass-flux measurements in the field(0.2-m depth), using ceramic solution samplers, and the newTDR method. The method measures mass flux of the solute at aparticular depth and not solute concentration. Thus, no assumptionsabout local water flux density are necessary in estimating F_L(T).The method also has the advantage that ${vartheta}$ can be measured at thesame location (soil volume) where the solute mass flux is measured.The method is limited to soils where addition of a solute pulsewill cause a measurable reduction in the reflected signal. Thisdepends on steady-state soil water content, EC_E at steady state,and the depth of measurement.

NOTES

^* Corresponding author.

Received for publication December 4, 1990.

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