Modeling GPR data to interpret porosity and DNAPL saturations for calibration of a 3-D multiphase flow simulation

Sneddon, Kristen W.; Powers, Michael H.; Johnson, Raymond H.; Poeter, Eileen

doi:10.3133/ofr02451

Cited by 15 publications

(18 citation statements)

References 30 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…DNAPL have very low permittivity values compared to water (2-4 as compared to 80) and are electrically resistive, leading to potentially strong GPR reflections off pooled DNAPL, and DNAPL may be detected in both unsaturated and saturated soils. GPR has been used to track DNAPL movement in soils (Brewster et al, 1995) and to interpret DNAPL saturation in soils (Sneddon, 2002). Like all surface geophysical methods, surface GPR surveys exhibit decreasing resolution with depth, and the effective penetration depth of GPR surveys can be fairly shallow, about 1-2 cm/Ωm of soil resistivity (Stewart, 1999).…”

Section: Statement Of Problemmentioning

confidence: 99%

A borehole geophysical method for detection and quantification of dense, non-aqueous phase liquids (DNAPL) in saturated soils

Stewart

North²

2006

Journal of Applied Geophysics

View full text Add to dashboard Cite

Section: Statement Of Problemmentioning

confidence: 99%

A borehole geophysical method for detection and quantification of dense, non-aqueous phase liquids (DNAPL) in saturated soils

Stewart

North²

2006

Journal of Applied Geophysics

View full text Add to dashboard Cite

“…However, while the BHS model provides a more thorough treatment of the physics governing dielectric properties, it is only accurate for known geometries and cumbersome to implement for heterogeneous and multiphase materials (Martinez and Byrnes, 2001). This is because it is a two-component model and needs to be applied iteratively to analyse three-material mixtures, such as a DNAPL/ water/sand system (e.g., Hu and Liu, 2000;Sneddon et al, 2002).…”

Section: Numerical Models and Their Linkagementioning

confidence: 99%

“…Redman et al (1991) performed a small, controlled release of TCE and successfully monitored the ensuing changes in dielectric stratigraphy. Subsequently, 770 l of TCE was released into an impermeable cell constructed within a saturated sand aquifer with surface dimensions of 9 m × 9 m and with a depth of 3.3 m. The extensive, temporal GPR data set is described in a series of publications (Greenhouse et al, 1993;Kueper et al, 1993;Annan, 1994, Brewster et al, 1995;Birken and Versteeg, 2000;Sneddon et al, 2002). Brewster and Annan (1994) used 200 MHz antennas to collect a time series of GPR images for approximately 2 months after the TCE release.…”

Section: Introductionmentioning

confidence: 99%

DNAPL mapping by ground penetrating radar examined via numerical simulation

Wilson

Power

Giannopoulos

et al. 2009

Journal of Applied Geophysics

View full text Add to dashboard Cite

“…The initial procedure for 1D modeling of GPR data from the sand tank is similar to the procedures discussed in Sneddon et al (2002). In all the GPR models, the early time data (0 to 3 ns) is not modeled because these data represent near-field effects produced by the antenna layout that does not represent subsurface conditions.…”

Section: One-dimensional Gpr Modelingmentioning

confidence: 99%

Interpreting DNAPL saturations in a laboratory‐scale injection using one‐ and two‐dimensional modeling of GPR data

Johnson¹,

Poeter²

2005

Groundwater Monitoring Rem

Self Cite

View full text Add to dashboard Cite

Ground‐penetrating radar (GPR) is used to track a dense non–aqueous phase liquid (DNAPL) injection in a laboratory sand tank. Before modeling, the GPR data provide a qualitative image of DNAPL saturation and movement. One‐dimensional (1D) GPR modeling provides a quantitative interpretation of DNAPL volume within a given thickness during and after the injection. DNAPL saturation in sublayers of a specified thickness could not be quantified because calibration of the 1D GPR model is nonunique when both permittivity and depth of multiple layers are unknown. One‐dimensional GPR modeling of the sand tank indicates geometric interferences in a small portion of the tank. These influences are removed from the interpretation using an alternate matching target. Two‐dimensional (2D) GPR modeling provides a qualitative interpretation of the DNAPL distribution through pattern matching and tests for possible 2D influences that are not accounted for in the 1D GPR modeling. Accurate quantitative interpretation of DNAPL volumes using GPR modeling requires (1) identification of a suitable target that produces a strong reflection and is not subject to any geometric interference; (2) knowledge of the exact depth of that target; and (3) use of two‐way radar‐wave travel times through the medium to the target to determine the permittivity of the intervening material, which eliminates reliance on signal amplitude. With geologic conditions that are suitable for GPR surveys (i.e., shallow depths, low electrical conductivities, and a known reflective target), the procedures in this laboratory study can be adapted to a field site to delineate shallow DNAPL source zones.

show abstract

Modeling GPR data to interpret porosity and DNAPL saturations for calibration of a 3-D multiphase flow simulation

Cited by 15 publications

References 30 publications

A borehole geophysical method for detection and quantification of dense, non-aqueous phase liquids (DNAPL) in saturated soils

A borehole geophysical method for detection and quantification of dense, non-aqueous phase liquids (DNAPL) in saturated soils

DNAPL mapping by ground penetrating radar examined via numerical simulation

Interpreting DNAPL saturations in a laboratory‐scale injection using one‐ and two‐dimensional modeling of GPR data

Contact Info

Product

Resources

About