Calibrating vadose zone models with time-lapse gravity data

Lars Christiansen; Eline Bojsen Haarder; Allan Bo Hansen; Majken Caroline Looms Zibar; Philip John Binning; Dan Rosbjerg; Ole Baltazar Andersen; Peter Bauer-Gottwein

Calibrating vadose zone models with time-lapse gravity data

Lars Christiansen, Eline Bojsen Haarder, Allan Bo Hansen, Majken Caroline Looms Zibar, Philip John Binning, Dan Rosbjerg, Ole Baltazar Andersen, Peter Bauer-Gottwein

Geology

11 Citations (Scopus)

Abstract

The vadose zone plays an important role in the hydrologic cycle. Various geophysical methods can determine soil water content variations in time and space in volumes ranging from a few cubic centimeters to several cubic meters. In contrast to the established methods, time-lapse gravity measurements of changes in soil water content do not rely on a petrophysical relationship between the measured quantity and the water content but give a direct measure of the mass change in the soil. Only recently has the vadose zone been systematically incorporated when ground-based gravity data are used to infer hydrologic information. In this study, changes in the soil water content gave rise to a measurable signal in a forced infiltration experiment on a 107-m2 grassland area. Time-lapse gravity data were able to constrain the van Genuchten soil hydraulic parameters in both a synthetic example and a field experiment with forced infiltration. The most significant reduction in parameter uncertainty was achieved for the saturated water content, while gravity data had some ability to constrain the saturated hydraulic conductivity and the van Genuchten n. Cross-borehole ground penetrating radar data were used to support the interpretation and control of the gravity data.

Original language	English
Journal	Vadose Zone Journal
Volume	10
Pages (from-to)	1034-1044
Number of pages	10
ISSN	1539-1663
Publication status	Published - Aug 2011

Cite this

@article{79ba5cb52e76477a9163c95005fd5b3d,

title = "Calibrating vadose zone models with time-lapse gravity data",

abstract = "The vadose zone plays an important role in the hydrologic cycle. Various geophysical methods can determine soil water content variations in time and space in volumes ranging from a few cubic centimeters to several cubic meters. In contrast to the established methods, time-lapse gravity measurements of changes in soil water content do not rely on a petrophysical relationship between the measured quantity and the water content but give a direct measure of the mass change in the soil. Only recently has the vadose zone been systematically incorporated when ground-based gravity data are used to infer hydrologic information. In this study, changes in the soil water content gave rise to a measurable signal in a forced infiltration experiment on a 107-m2 grassland area. Time-lapse gravity data were able to constrain the van Genuchten soil hydraulic parameters in both a synthetic example and a field experiment with forced infiltration. The most significant reduction in parameter uncertainty was achieved for the saturated water content, while gravity data had some ability to constrain the saturated hydraulic conductivity and the van Genuchten n. Cross-borehole ground penetrating radar data were used to support the interpretation and control of the gravity data.",

author = "Lars Christiansen and Haarder, {Eline Bojsen} and Hansen, {Allan Bo} and Zibar, {Majken Caroline Looms} and Binning, {Philip John} and Dan Rosbjerg and Andersen, {Ole Baltazar} and Peter Bauer-Gottwein",

year = "2011",

month = aug,

language = "English",

volume = "10",

pages = "1034--1044",

journal = "Vadose Zone Journal",

issn = "1539-1663",

publisher = "GeoScienceWorld",

}

TY - JOUR

T1 - Calibrating vadose zone models with time-lapse gravity data

AU - Christiansen, Lars

AU - Haarder, Eline Bojsen

AU - Hansen, Allan Bo

AU - Zibar, Majken Caroline Looms

AU - Binning, Philip John

AU - Rosbjerg, Dan

AU - Andersen, Ole Baltazar

AU - Bauer-Gottwein, Peter

PY - 2011/8

Y1 - 2011/8

N2 - The vadose zone plays an important role in the hydrologic cycle. Various geophysical methods can determine soil water content variations in time and space in volumes ranging from a few cubic centimeters to several cubic meters. In contrast to the established methods, time-lapse gravity measurements of changes in soil water content do not rely on a petrophysical relationship between the measured quantity and the water content but give a direct measure of the mass change in the soil. Only recently has the vadose zone been systematically incorporated when ground-based gravity data are used to infer hydrologic information. In this study, changes in the soil water content gave rise to a measurable signal in a forced infiltration experiment on a 107-m2 grassland area. Time-lapse gravity data were able to constrain the van Genuchten soil hydraulic parameters in both a synthetic example and a field experiment with forced infiltration. The most significant reduction in parameter uncertainty was achieved for the saturated water content, while gravity data had some ability to constrain the saturated hydraulic conductivity and the van Genuchten n. Cross-borehole ground penetrating radar data were used to support the interpretation and control of the gravity data.

AB - The vadose zone plays an important role in the hydrologic cycle. Various geophysical methods can determine soil water content variations in time and space in volumes ranging from a few cubic centimeters to several cubic meters. In contrast to the established methods, time-lapse gravity measurements of changes in soil water content do not rely on a petrophysical relationship between the measured quantity and the water content but give a direct measure of the mass change in the soil. Only recently has the vadose zone been systematically incorporated when ground-based gravity data are used to infer hydrologic information. In this study, changes in the soil water content gave rise to a measurable signal in a forced infiltration experiment on a 107-m2 grassland area. Time-lapse gravity data were able to constrain the van Genuchten soil hydraulic parameters in both a synthetic example and a field experiment with forced infiltration. The most significant reduction in parameter uncertainty was achieved for the saturated water content, while gravity data had some ability to constrain the saturated hydraulic conductivity and the van Genuchten n. Cross-borehole ground penetrating radar data were used to support the interpretation and control of the gravity data.

M3 - Journal article

SN - 1539-1663

VL - 10

SP - 1034

EP - 1044

JO - Vadose Zone Journal

JF - Vadose Zone Journal

ER -

Calibrating vadose zone models with time-lapse gravity data

Abstract

Fingerprint

Cite this