An airborne tensor VLF system. From concept to realization1

Laust B. Pedersen; Wei Qian; Lars Dynesius; Ping Zhang

doi:10.1111/j.1365-2478.1994.tb00246.x

E-ISSN: 1365-2478

An airborne tensor VLF system. From concept to realization¹
Authors Laust B. Pedersen¹, Wei Qian^1,2, Lars Dynesius¹, Ping Zhang^1,3
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Affiliations: ¹ Department of Solid Earth Physics, Uppsala University, S–752 36, Uppsala, Sweden. ² Geological Survey of Canada, Continental Geoscience Division, 1 Observatory Cresent, Ottawa, Canada, K1A OY3. Formerly at ³ Department of Mineral Engineering, École Polytechnique, CP 6079, succ. A, Montréal, Canada, H3C 3A7. Formerly at
Source: Geophysical Prospecting, Volume 42, Issue 8, Nov 1994, p. 863 - 883
DOI: https://doi.org/10.1111/j.1365-2478.1994.tb00246.x
- Published online: 28 Apr 2006

Abstract

Radio signals from very low frequency (VLF) transmitters distributed world‐wide have been used for several decades to study the lateral variations of the electrical conductivity in the upper few hundred metres of the earth's crust. Traditionally, in airborne applications, the total magnetic fields from one or two transmitters are measured to form the basis for construction of maps that primarily show those conductive structures that are parallel or subparallel to the direction to the transmitters. The tensor VLF technique described in this paper makes use of all signals available in a predefined frequency band to construct transfer functions relating the vertical magnetic field and the two horizontal magnetic field components. These transfer functions are uniquely determined for a particular measuring site and contain information about the lateral conductivity variations in all directions. First experiences with real field data, acquired during a test survey in Sweden, show that maps of the so‐called peaker, the spatial divergence of the transfer functions, give an image of the conducting structures. Most of the structures can be correlated to small valleys filled with conducting sediments or valleys underlain by conductive fracture zones in the crystalline rocks.

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References

BaranovW.1975. Potential Fields and their Transformations in Applied Geophysics. Gebrü der Borntraeger.
[Google Scholar]
BarbourD.M. and ThrulowJ.C.1982. Case histories of two massive sulphide discoveries in Central Newfoundland. In: Prospecting in Areas of Glaciated Terrain‐1982, pp. 300–321. Can Inst. Min. and Metal.
[Google Scholar]
BarfieldR.H.1934. Some measurements of the electric constants of the ground at short wavelengths by the wave tilt method. Proceeding of the IEEE75, 214–220.
[Google Scholar]
FeldmanC.B.1933. The optical behaviour of the ground short radio waves. Proceedings of the IEEE21, 764–801.
[Google Scholar]
FischerG., Le QuangB.V. and MullerI.1983. VLF ground surveys, a powerful tool for the study of shallow two‐dimensional structures. Geophysical Prospecting31, 977–991.
[Google Scholar]
GreenhouseJ.P. and HarrisR.D.1983. Migration of contaminants in ground water at a landfill: a case study. Journal of Hydrology63, 177–197.
[Google Scholar]
Bergman
HenkelH. and ErikssonL.1980. Interpretation of low altitude airborne magnetic and VLF measurements for identification of fracture zones. In: Proceedings of Subsurface Space (Ed. Bergman ). Stockholm .
M.N.Nabighian
McNeillJ.D. and LabsonV.F.1989. Geological mapping using VLF radio fields. In: Electromagnetic methods in applied geophysics, 2, part B (Ed. M.N.Nabighian ), ch. 7. SEG, Tulsa .
[Google Scholar]
Menke, W.1984. Geophysical Data Analysis: Discrete Inverse Theory. Academic Press Inc.
[Google Scholar]
MullernC.F. and ErikssonL.1982. Analysis of VLF anomalies encountered when prospecting for groundwater in rock. National Swedish Board for Technical Development Report 80-4151.
[Google Scholar]
MullernC.F. and ErikssonL.1981. Testing VLF‐resistivity measurements in order to locate saline groundwater. SGU rapporter och meddelanden No. 27.
[Google Scholar]
PaalG.1965. Ore prospecting based on VLF‐radio signals. Geoexploration3, 139–147.
[Google Scholar]
PaalG.1968. Very low frequency measurements in northern Sweden. Geoexploration6, 141–149.
[Google Scholar]
PedersenL.B.1982. The magnetotelluric impedance tensor‐ its random and bias errors. Geophysical Prospecting30, 188–210.
[Google Scholar]
PedersenL.B. and RasmussenT.M.1989. Inversion of magnetotelluric data, a non‐linear least‐squares approach. Geophysical Prospecting37, 669–695.
[Google Scholar]
PedersenL.B., ZhangP. and RasmussenT.M.1987. Tensor VLF measurements in the Siljan area. Gasproject Report Series, No. U (G) 19877sol;52, Vattenfall, Sweden .
[Google Scholar]
PoddarM. and RathorB.S.1983. VLF survey of the weathered layer in southern India. Geophysical Prospecting31, 524–537.
[Google Scholar]
QianW. and BoernerD.E., 1994. Electromagnetic modelling of buried line conductors using an integral equation. Geophysical Journal International, in press.
[Google Scholar]
SinhaA.K.1989. Magnetic wavetilt measurements for geological fracture mapping. Geophysical Prospecting37, 427–445.
[Google Scholar]
SinhaA.K., and HaylesJ.C.1988. Experiences with a local loop VLF transmitter for geological studies in the Canadian nuclear fuel waste management program. Geoexploration25, 37–60.
[Google Scholar]
Smith‐RoseR.L.1933. The electrical properties of soil for alternating currents at radio frequenciesProceedings of the Royal Society of London140, 359–377.
[Google Scholar]
ValleeM.A., ChouteauM. and PalackyG.J.1992. Variations of the VLF‐EM primary field: Analysis of airborne survey data, New Brunswick, Canada. Geophysics57, 181–186.
[Google Scholar]
VozoffK.1972. The magnetotelluric method in exploration of sedimentary basins. Geophysics37, 98–171.
[Google Scholar]
ZhangP., PedersenL.B., MareschalM. and ChouteauM.1993. Channelling contribution to tipper vectors: a magnetic equivalent to electrical distortion. Geophysical Journal International113, 693–700.
[Google Scholar]
ZhangP., RobertsR.G. and PedersenL.B.1987. Magnetotelluric strike rules. Geophysics52, 267–278.
[Google Scholar]

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Article Type: Research Article

An airborne tensor VLF system. From concept to realization¹

Abstract

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