Distinguishing Capillary Fringe Reflection in a GPR Profile for Precise Water Table Depth Estimation in a Boreal Podzolic Soil Field

Illawathure, Chameera and Cheema, Mumtaz and Kavanagh, Vanessa and Galagedara, Lakshman (2020) Distinguishing Capillary Fringe Reflection in a GPR Profile for Precise Water Table Depth Estimation in a Boreal Podzolic Soil Field. Water, 12 (6). ISSN 2073-4441

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Abstract

Relative permittivity and soil moisture are highly correlated; therefore, the top boundary of saturated soil gives strong reflections in ground-penetrating radar (GPR) profiles. Conventionally in shallow groundwater systems, the first dominant reflection comes from the capillary fringe, followed by the actual water table. The objective of this study was to calibrate and validate a site-specific relationship between GPR-estimated depth to the capillary fringe (DCF) and measured water table depth (WTDm). Common midpoint (CMP) GPR surveys were carried out in order to estimate the average radar velocity, and common offset (CO) surveys were carried out to map the water table variability in the 2017 and 2018 growing seasons. Also, GPR sampling volume geometry with radar velocities in different soil layers was considered to support the CMP estimations. The regression model (R2 = 0.9778) between DCF and WTDm, developed for the site in 2017, was validated using data from 2018. A regression analysis between DCF and WTDm for the two growing seasons suggested an average capillary height of 0.741 m (R2 = 0.911, n = 16), which is compatible with the existing literature under similar soil conditions. The described method should be further developed over several growing seasons to encompass wider water table variability.

Item Type: Article
URI: http://research.library.mun.ca/id/eprint/14866
Item ID: 14866
Additional Information: Memorial University Open Access Author's Fund
Keywords: capillary fringe, GPR, monitoring, radar velocity, wave reflection, water table depth
Department(s): Grenfell Campus > School of Science and the Environment
Date: 11 June 2020
Date Type: Publication
Digital Object Identifier (DOI): https://doi.org/10.3390/w12061670
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