Magnetic Base Station Deceptions, a magnetovariational analysis along the Ligurian Sea coast, Italy
Author(s)
Language
English
Obiettivo Specifico
3.4. Geomagnetismo
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
3/50 (2007)
Publisher
Editrice Compositori
Pages (printed)
397-406
Date Issued
June 2007
Abstract
Reliability of high resolution airborne and shipborne magnetic surveys depends on accurate removal of temporal
variations from the recorded total magnetic field intensity data. At mid latitudes, one or a few base stations are typically
located within or near the survey area and are used to monitor and remove time dependent variations. These
are usually assumed to be of external origin and uniform throughout the survey area. Here we investigate the
influence on the magnetic base station correction of the time varying magnetic field variations generated by internal
telluric currents flowing in anomalous regional 2D/3D conductivity structures. The study is based on the statistical
analysis of a data set collected by four magnetovariational stations installed in northwestern Italy. The variometer stations
were evenly placed with a spacing of about 60 km along a profile roughly parallel to the coastline. They recorded
the geomagnetic field from the beginning to the end of April 2005, with a sampling rate of 0.33 Hz. Cross-correlation
and coherence analysis applied to a subset of 125 five hours long magnetic events indicates that, for periods
longer than 400 s, there is an high correlation between the horizontal magnetic field components at the different stations.
This indicates spatial uniformity of the source field and of the induced currents in the 1D Earth. Additionally,
the pattern of the induction arrows, estimated from single site transfer functions, reveals a clear electromagnetic signature
of the Sestri-Voltaggio line, interpreted as a major regional tectonic boundary. Induced telluric currents flowing
through this 2D/3D electrical conductivity discontinuity affect mainly the vertical magnetic component at the
closer locations. By comparing this component at near (32 km) and far (70 km) stations, we have found that the mean
value of the power spectra ratio, due to the electromagnetic induced field, is about 1.8 in the frequency band ranging
from 2.5×10−3 to 5.5×10−5 Hz. This energy, folded in the spatial domain of an hypothetical survey in this region
produces unwanted noise in the dataset. Considering a fifth of nyquist frequency the optimal tie-line spacing to assure
complete noise removal would be 1 km and 15 km for a rover speed of 6 knots (marine magnetic survey) and
100 knots (aeromagnetic survey) respectively. Similar power spectra analysis can be applied elsewhere to optimise
tie-line spacing for levelling and filtering parameters utlilised for microlevelling.
variations from the recorded total magnetic field intensity data. At mid latitudes, one or a few base stations are typically
located within or near the survey area and are used to monitor and remove time dependent variations. These
are usually assumed to be of external origin and uniform throughout the survey area. Here we investigate the
influence on the magnetic base station correction of the time varying magnetic field variations generated by internal
telluric currents flowing in anomalous regional 2D/3D conductivity structures. The study is based on the statistical
analysis of a data set collected by four magnetovariational stations installed in northwestern Italy. The variometer stations
were evenly placed with a spacing of about 60 km along a profile roughly parallel to the coastline. They recorded
the geomagnetic field from the beginning to the end of April 2005, with a sampling rate of 0.33 Hz. Cross-correlation
and coherence analysis applied to a subset of 125 five hours long magnetic events indicates that, for periods
longer than 400 s, there is an high correlation between the horizontal magnetic field components at the different stations.
This indicates spatial uniformity of the source field and of the induced currents in the 1D Earth. Additionally,
the pattern of the induction arrows, estimated from single site transfer functions, reveals a clear electromagnetic signature
of the Sestri-Voltaggio line, interpreted as a major regional tectonic boundary. Induced telluric currents flowing
through this 2D/3D electrical conductivity discontinuity affect mainly the vertical magnetic component at the
closer locations. By comparing this component at near (32 km) and far (70 km) stations, we have found that the mean
value of the power spectra ratio, due to the electromagnetic induced field, is about 1.8 in the frequency band ranging
from 2.5×10−3 to 5.5×10−5 Hz. This energy, folded in the spatial domain of an hypothetical survey in this region
produces unwanted noise in the dataset. Considering a fifth of nyquist frequency the optimal tie-line spacing to assure
complete noise removal would be 1 km and 15 km for a rover speed of 6 knots (marine magnetic survey) and
100 knots (aeromagnetic survey) respectively. Similar power spectra analysis can be applied elsewhere to optimise
tie-line spacing for levelling and filtering parameters utlilised for microlevelling.
References
ARMADILLO, E., E. BOZZO, V. CERV, A. DE SANTIS, D. DI
MAURO, M. GAMBETTA, A. MELONI, J. PEK and F. SPERANZA
(2001): Geomagnetic depth sounding in the
Northern Apennines (Italy), Earth Planets Space, 53,
385-396.
ARMADILLO, E. , F. FERRACCIOLI, G. TABELLARIO and E. BOZZO
(2004): Electrical structure across a major icecovered
fault belt in Northern Victoria land (East Antarctica),
Geophys. Res. Lett., 31, L10615, doi: 10.1029/
2004GL019903.
ARORA, B.N., N.B. TRIVEDI, I. VITORELLO, A.L. PADILHA, A.
RIGOTI and F.H. CHAMALAUN (1999): Overview of Geomagnetic
Deep Soundings (GDS) as applied in the
Parnaiba basin, north-northeast Brazil, Rev. Bras.
Geofis., 17 (1), 44-65.
CAMPBELL, W.H., C.E. BARTON, F.H. CHAMALAUN and W.
WELSH (1988): Quiet-day ionospheric currents and
their application to upper mantle conductivity in Australia,
Earth Planets Space, 50, 347-360.
CAPPONI, G. (1991): Megastructure of the south eastern part
of the Voltri Group (Ligurian Alps): a tentative interpretation,
Boll. Soc. Geol. Ital., 110, 391-403.
CORTESOGNO, L. and D. HACCARD (1984): Note illustrative
alla carta geologica della Zona SestriVoltaggio, Mem.
Soc. Geol. Ital., 28, 115-150.
CRISPINI, L. and G. CAPPONI (2001): Tectonic evolution of
the Voltri Group and Sestri Voltaggio Zone (southern
limit of the NW Alps): a review, Ofioliti, 26 (2a), 161-
164.
DI MAURO, D., E. ARMADILLO, E. BOZZO, V. CERV, A. DE
SANTIS, M. GAMBETTA and A. MELONI (1988): GDS
(Geomagnetic Depth Soundings) in Italy: applications
and perspectives, Ann. Geofis., 41 (3), 477-490.
EGBERT, G.D. and J.R. BOOKER (1986): Robust estimation
of geomagnetic transfer functions, Geophys. J.R. Astron.
Soc., 87, 173-194.
FEDERICO, L., G. CAPPONI, L. CRISPINI, M. SCAMBELLURI
and I.M. VILLA (2005): 39Ar/ 40Ar dating of high pressure
rocks from the Ligurian Alps: evidence for a continuous
subductionexhumation cycle, Earth Planet.
Sci. Lett., 240, 668-680.
FERRACCIOLI, F., M. GAMBETTA and E. BOZZO (1998): Microlevelling
precedures applied to regional aeromagnetic
data: an example from the Transantarctic Mountains
(Antarctica), Geophys. Prospect., 46, 177-196.
GOUGH, D.I. and M.R. INGHAM (1983): Interpretation methods
for magnetometer arrays, Rev. Geophys. Space
Phys., 21 (4), 805-827.
HERMANCE, J.F. (1995): Electrical conductivity models of
the crust and mantle, in Global Earth Physics, an
Handbook of Physical Constants (Am. Geophys. Un.
Shelf 1), 190-205.
HITCHMAN, A.P., F.E.M. LILLEY and P.R. MILLIGAN (2001):
Electromagnetic induction information from differences
at aeromagnetic crossover points, Geophys. J.
Int., 145, 277-290.
HJELTH, S.E. and T. KORJA (1993): Lithospheric and uppermantle
structures, results of electromagnetic sounding
in Europe, Phys. Earth Planet. Inter., 79, 137-77.
HOOGERDUIJN STRATING, E.H. (1991): The evolution of the
Piemonte Ligurian ocean. A structural study of ophiolite
complexes in Liguria (NW Italy), PhD Thesis (University
of Utrecht), pp. 127.
HYNDMAN, R.D. (1988): Dipping seismic reflectors, electrically
conductive zones, and trapped water in the crust
over a subducting plate, J. Geophys. Res., 93 (B11),
13391-13405.
INGHAM, M.R., D.K. BINGHAM and D.I. GOUGH (1983): A
magnetovariational study of a geothermal anomaly,
Geophys. J.R. Astron. Soc., 72, 597-618.
JIRACEK, G.R., V. HAAK and K.H. OLSEN (1995): Practical
magnetotellurics in a continental rift environment, in
Continental Rifts: Evolution, Structure, Tectonics, edited
by K.H. OLSEN (Elsevier, Amsterdam), 103-129.
JONES, A.G. (1999): Imaging the continental upper mantle
using electromagnetic methods, Lithos, 48 (1-4), 57-80.
JORDING, A., L. FERRARI, J. ARZATE and H. JDICKE (2000):
Crustal variations and terrane boundaries in Southern
Mexico as imaged by magnetotelluric transfer functions,
Tectonophysics, 327 (1-2), 1-13.
LEDO, J., A.G. JONES and I.J. FERGUSON (2002): Electromagnetic
images of a strikeslip fault: the Tintina Fault-
Northern Canadian, Geophys. Res. Lett., 29 (8), 1225,
doi: 10.1029/2001GL013408.
LUYENDYK, A.P.J. (1997): Processing of airborne magnetic
data, AGSO J. Austr. Geol. Geophys., 17 (2), 31-38.
MAKRIS, J., F. EGLOFF, R. NICOLICH and R. RIHM (1999):
Crustal structure from the Ligurian Sea to the Northern
Apennines a wide angle seismic transect, Tectonophysics,
301, 305-319.
SAKKAS, V., M.A. MEJU, M.A. KHAN, V. HAAK and F. SIMPSON
(2002): Magnetotelluric images of the crustal structure
of Chyulu Hills volcanic field, Kenya, Tectonophysics,
346, 169-185.
SOUL, S.J. and M.J. PARSON (1998): Levelling of aeromagnetic
Data, Can. J. Explor. Geophys., 34 (1-2), 9-15.
WELCH, P.D. (1967): The use of fast Fourier transform for
the estimation of power spectra: a method based on
time averaging over short, modified periodograms,
IEEE Trans. Audio Electroacoust., 15 (2), 70-73.
MAURO, M. GAMBETTA, A. MELONI, J. PEK and F. SPERANZA
(2001): Geomagnetic depth sounding in the
Northern Apennines (Italy), Earth Planets Space, 53,
385-396.
ARMADILLO, E. , F. FERRACCIOLI, G. TABELLARIO and E. BOZZO
(2004): Electrical structure across a major icecovered
fault belt in Northern Victoria land (East Antarctica),
Geophys. Res. Lett., 31, L10615, doi: 10.1029/
2004GL019903.
ARORA, B.N., N.B. TRIVEDI, I. VITORELLO, A.L. PADILHA, A.
RIGOTI and F.H. CHAMALAUN (1999): Overview of Geomagnetic
Deep Soundings (GDS) as applied in the
Parnaiba basin, north-northeast Brazil, Rev. Bras.
Geofis., 17 (1), 44-65.
CAMPBELL, W.H., C.E. BARTON, F.H. CHAMALAUN and W.
WELSH (1988): Quiet-day ionospheric currents and
their application to upper mantle conductivity in Australia,
Earth Planets Space, 50, 347-360.
CAPPONI, G. (1991): Megastructure of the south eastern part
of the Voltri Group (Ligurian Alps): a tentative interpretation,
Boll. Soc. Geol. Ital., 110, 391-403.
CORTESOGNO, L. and D. HACCARD (1984): Note illustrative
alla carta geologica della Zona SestriVoltaggio, Mem.
Soc. Geol. Ital., 28, 115-150.
CRISPINI, L. and G. CAPPONI (2001): Tectonic evolution of
the Voltri Group and Sestri Voltaggio Zone (southern
limit of the NW Alps): a review, Ofioliti, 26 (2a), 161-
164.
DI MAURO, D., E. ARMADILLO, E. BOZZO, V. CERV, A. DE
SANTIS, M. GAMBETTA and A. MELONI (1988): GDS
(Geomagnetic Depth Soundings) in Italy: applications
and perspectives, Ann. Geofis., 41 (3), 477-490.
EGBERT, G.D. and J.R. BOOKER (1986): Robust estimation
of geomagnetic transfer functions, Geophys. J.R. Astron.
Soc., 87, 173-194.
FEDERICO, L., G. CAPPONI, L. CRISPINI, M. SCAMBELLURI
and I.M. VILLA (2005): 39Ar/ 40Ar dating of high pressure
rocks from the Ligurian Alps: evidence for a continuous
subductionexhumation cycle, Earth Planet.
Sci. Lett., 240, 668-680.
FERRACCIOLI, F., M. GAMBETTA and E. BOZZO (1998): Microlevelling
precedures applied to regional aeromagnetic
data: an example from the Transantarctic Mountains
(Antarctica), Geophys. Prospect., 46, 177-196.
GOUGH, D.I. and M.R. INGHAM (1983): Interpretation methods
for magnetometer arrays, Rev. Geophys. Space
Phys., 21 (4), 805-827.
HERMANCE, J.F. (1995): Electrical conductivity models of
the crust and mantle, in Global Earth Physics, an
Handbook of Physical Constants (Am. Geophys. Un.
Shelf 1), 190-205.
HITCHMAN, A.P., F.E.M. LILLEY and P.R. MILLIGAN (2001):
Electromagnetic induction information from differences
at aeromagnetic crossover points, Geophys. J.
Int., 145, 277-290.
HJELTH, S.E. and T. KORJA (1993): Lithospheric and uppermantle
structures, results of electromagnetic sounding
in Europe, Phys. Earth Planet. Inter., 79, 137-77.
HOOGERDUIJN STRATING, E.H. (1991): The evolution of the
Piemonte Ligurian ocean. A structural study of ophiolite
complexes in Liguria (NW Italy), PhD Thesis (University
of Utrecht), pp. 127.
HYNDMAN, R.D. (1988): Dipping seismic reflectors, electrically
conductive zones, and trapped water in the crust
over a subducting plate, J. Geophys. Res., 93 (B11),
13391-13405.
INGHAM, M.R., D.K. BINGHAM and D.I. GOUGH (1983): A
magnetovariational study of a geothermal anomaly,
Geophys. J.R. Astron. Soc., 72, 597-618.
JIRACEK, G.R., V. HAAK and K.H. OLSEN (1995): Practical
magnetotellurics in a continental rift environment, in
Continental Rifts: Evolution, Structure, Tectonics, edited
by K.H. OLSEN (Elsevier, Amsterdam), 103-129.
JONES, A.G. (1999): Imaging the continental upper mantle
using electromagnetic methods, Lithos, 48 (1-4), 57-80.
JORDING, A., L. FERRARI, J. ARZATE and H. JDICKE (2000):
Crustal variations and terrane boundaries in Southern
Mexico as imaged by magnetotelluric transfer functions,
Tectonophysics, 327 (1-2), 1-13.
LEDO, J., A.G. JONES and I.J. FERGUSON (2002): Electromagnetic
images of a strikeslip fault: the Tintina Fault-
Northern Canadian, Geophys. Res. Lett., 29 (8), 1225,
doi: 10.1029/2001GL013408.
LUYENDYK, A.P.J. (1997): Processing of airborne magnetic
data, AGSO J. Austr. Geol. Geophys., 17 (2), 31-38.
MAKRIS, J., F. EGLOFF, R. NICOLICH and R. RIHM (1999):
Crustal structure from the Ligurian Sea to the Northern
Apennines a wide angle seismic transect, Tectonophysics,
301, 305-319.
SAKKAS, V., M.A. MEJU, M.A. KHAN, V. HAAK and F. SIMPSON
(2002): Magnetotelluric images of the crustal structure
of Chyulu Hills volcanic field, Kenya, Tectonophysics,
346, 169-185.
SOUL, S.J. and M.J. PARSON (1998): Levelling of aeromagnetic
Data, Can. J. Explor. Geophys., 34 (1-2), 9-15.
WELCH, P.D. (1967): The use of fast Fourier transform for
the estimation of power spectra: a method based on
time averaging over short, modified periodograms,
IEEE Trans. Audio Electroacoust., 15 (2), 70-73.
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