Abstract
Abstract. We show the potential of on-ground Ground-Penetrating Radar (GPR) to identify the parameterisation of the soil water retention curve, i.e. its functional form, with a semi-quantitative analysis based on numerical simulations of the radar signal. An imbibition and drainage experiment has been conducted at the ASSESS-GPR site to establish a fluctuating water table, while an on-ground GPR antenna recorded traces over time at a fixed location. These measurements allow to identify and track the capillary fringe in the soil. The typical dynamics of soil water content with a transient water table can be deduced from the recorded radargrams. The characteristic reflections from the capillary fringes in model soils that are described by commonly used hydraulic parameterisations are investigated by numerical simulations. The parameterisations used are (i) full van Genuchten, (ii) simplified van Genuchten with m = 1 − 1/n and (iii) Brooks–Corey. All three yield characteristically different reflections, which allows the identification of an appropriate parameterisation by comparing to the measured signals. We show that for the sand used here, these signals are not consistent with the commonly used simplified van Genuchten parameterisation with m = 1 − 1/n.
Highlights
Parameterising the soil hydraulic properties is essential for modelling and predicting water movement in soils
A main aspect in both strategies is the requirement of a suitable parameterisation, which is capable of representing the soil of interest. Used in this context are the parameterisations of van Genuchten (1980) and Brooks (1966) for the soil water characteristic, typically combined with the parameterisation of Mualem (1976) for the soil hydraulic conductivity
A wave with a much longer wavelength on the other hand will experience this feature as a highly localised one and will be reflected. With this understanding we investigate and explain the characteristic reflections from permittivity profiles calculated with the different hydraulic parameterisations
Summary
Parameterising the soil hydraulic properties is essential for modelling and predicting water movement in soils. Choosing a different way, van der Kruk et al (2010) demonstrated that low-velocity layers induced by precipitation events act as a wave-guide and allow for very precise estimations of thickness and water content of these layers With this GPR emerges as a valuable tool in soil hydrology to monitor the dynamics of water content. While it could be demonstrated that GPR reflection signals can provide enough information to estimate the hydraulic parameters of a given parameterisation (most precisely by Lambot et al, 2004a, 2009), we here focus on another problem in hydraulic parameter estimation already mentioned above: the identification of an appropriate parameterisation This is feasible because of the high sensitivity of GPR reflection signals to small differences in the water content distribution and opens the door to more accurate non-invasive measurements of soil hydraulic properties of the field scale
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