Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles

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Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles. / Khan, A.; Koch, S.; Shankland, T. J.; Zunino, A.; Connolly, J. A.D.

The Earth's Heterogeneous Mantle: A Geophysical, Geodynamical, and Geochemical Perspective. Springer, 2015. s. 145-171.

Publikation: Bidrag til bog/antologi/rapportBidrag til bog/antologiForskningfagfællebedømt

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Khan, A, Koch, S, Shankland, TJ, Zunino, A & Connolly, JAD 2015, Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles. i The Earth's Heterogeneous Mantle: A Geophysical, Geodynamical, and Geochemical Perspective. Springer, s. 145-171. https://doi.org/10.1007/978-3-319-15627-9_5

APA

Khan, A., Koch, S., Shankland, T. J., Zunino, A., & Connolly, J. A. D. (2015). Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles. I The Earth's Heterogeneous Mantle: A Geophysical, Geodynamical, and Geochemical Perspective (s. 145-171). Springer. https://doi.org/10.1007/978-3-319-15627-9_5

Vancouver

Khan A, Koch S, Shankland TJ, Zunino A, Connolly JAD. Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles. I The Earth's Heterogeneous Mantle: A Geophysical, Geodynamical, and Geochemical Perspective. Springer. 2015. s. 145-171 https://doi.org/10.1007/978-3-319-15627-9_5

Author

Khan, A. ; Koch, S. ; Shankland, T. J. ; Zunino, A. ; Connolly, J. A.D. / Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles. The Earth's Heterogeneous Mantle: A Geophysical, Geodynamical, and Geochemical Perspective. Springer, 2015. s. 145-171

Bibtex

@inbook{e2d038652ba042d4ad55aec6fbc081e8,
title = "Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles",
abstract = "We present maps of the three-dimensional density (ρ), electrical conductivity (σ), and shear-wave speed (VS) structure of the mantle beneath Australia and surrounding ocean in the depth range of 100–800 km. These maps derived from stochastic inversion of seismic surface-wave dispersion data, thermodynamic modeling of mantle mineral phase equilibria, and laboratory-based conductivity models. Because composition and temperature act as fundamental parameters, we obtain naturally scaled maps of shear-wave speed, density, and electrical conductivity that depend only on composition, physical conditions (pressure and temperature), and laboratory measurements of the conductivity of anhydrous mantle minerals. The maps show that in the upper mantle ρ,σ and VS follow the continental-tectonic division that separates the older central and western parts of Australia from the younger eastern part. The lithosphere beneath the central and western cratonic areas appears to be relatively cold and Fe-depleted, and this is reflected in fast shear-wave speeds, high densities, and low conductivities. In contrast, the lithosphere underneath younger regions is relatively hot and enriched with Fe, which is manifested in slow shear-wave speeds, low densities, and high conductivities. This trend appears to continue to depths well below 300 km. The slow-fast shear-wave speed distribution found here is also observed in independent seismic tomographic models of the Australian region, whereas the coupled slow-fast shear-wave speed, low-high density, and high-low electrical conductivity distribution has not been observed previously. Toward the bottom of the upper mantle at 400 km depth marking the olivine ⃗ wadsleyite transformation (the “410–km” seismic discontinuity), the correlation between VS, ρ, and σ weakens. In the transition zone, VS, ρ, and are much less correlated indicating a significant compositional contribution to lateral heterogeneity. In particular, in the lower transition zone, ρ and σ appear to be governed mostly by variations in Fe/(Fe + Mg), whereas lateral variations in VS result from changes in (Mg + Fe)/Si and not, as observed in the upper mantle, from temperature variations. Lower mantle lateral variations in thermochemical parameters appear to smooth out, which suggests a generally homogeneous lower mantle in agreement with seismic tomographic images of the lower mantle. As a test of the regional surface-wave-based conductivity model, we computed magnetic fields of 24 h Sqvariations and compared these to observations. The comparison shows that while our predicted conductivity model improves the fit to observations relative to a one-dimensional model, amplitudes of the computed conductivity anomalies appear not to be large enough to enable these to be discriminated at present.",
keywords = "Electrical conductivity, Electromagnetic sounding, Mantle composition, Mantle temperatures, Phase equilibria, Seismic wave-speed, Surface waves, Tomography",
author = "A. Khan and S. Koch and Shankland, {T. J.} and A. Zunino and Connolly, {J. A.D.}",
year = "2015",
month = jan,
day = "1",
doi = "10.1007/978-3-319-15627-9_5",
language = "English",
isbn = "9783319156262",
pages = "145--171",
booktitle = "The Earth's Heterogeneous Mantle",
publisher = "Springer",
address = "Switzerland",

}

RIS

TY - CHAP

T1 - Relationships between seismic wave-Speed, density, and electrical conductivity beneath Australia from seismology, mineralogy, and laboratory-based conductivity profiles

AU - Khan, A.

AU - Koch, S.

AU - Shankland, T. J.

AU - Zunino, A.

AU - Connolly, J. A.D.

PY - 2015/1/1

Y1 - 2015/1/1

N2 - We present maps of the three-dimensional density (ρ), electrical conductivity (σ), and shear-wave speed (VS) structure of the mantle beneath Australia and surrounding ocean in the depth range of 100–800 km. These maps derived from stochastic inversion of seismic surface-wave dispersion data, thermodynamic modeling of mantle mineral phase equilibria, and laboratory-based conductivity models. Because composition and temperature act as fundamental parameters, we obtain naturally scaled maps of shear-wave speed, density, and electrical conductivity that depend only on composition, physical conditions (pressure and temperature), and laboratory measurements of the conductivity of anhydrous mantle minerals. The maps show that in the upper mantle ρ,σ and VS follow the continental-tectonic division that separates the older central and western parts of Australia from the younger eastern part. The lithosphere beneath the central and western cratonic areas appears to be relatively cold and Fe-depleted, and this is reflected in fast shear-wave speeds, high densities, and low conductivities. In contrast, the lithosphere underneath younger regions is relatively hot and enriched with Fe, which is manifested in slow shear-wave speeds, low densities, and high conductivities. This trend appears to continue to depths well below 300 km. The slow-fast shear-wave speed distribution found here is also observed in independent seismic tomographic models of the Australian region, whereas the coupled slow-fast shear-wave speed, low-high density, and high-low electrical conductivity distribution has not been observed previously. Toward the bottom of the upper mantle at 400 km depth marking the olivine ⃗ wadsleyite transformation (the “410–km” seismic discontinuity), the correlation between VS, ρ, and σ weakens. In the transition zone, VS, ρ, and are much less correlated indicating a significant compositional contribution to lateral heterogeneity. In particular, in the lower transition zone, ρ and σ appear to be governed mostly by variations in Fe/(Fe + Mg), whereas lateral variations in VS result from changes in (Mg + Fe)/Si and not, as observed in the upper mantle, from temperature variations. Lower mantle lateral variations in thermochemical parameters appear to smooth out, which suggests a generally homogeneous lower mantle in agreement with seismic tomographic images of the lower mantle. As a test of the regional surface-wave-based conductivity model, we computed magnetic fields of 24 h Sqvariations and compared these to observations. The comparison shows that while our predicted conductivity model improves the fit to observations relative to a one-dimensional model, amplitudes of the computed conductivity anomalies appear not to be large enough to enable these to be discriminated at present.

AB - We present maps of the three-dimensional density (ρ), electrical conductivity (σ), and shear-wave speed (VS) structure of the mantle beneath Australia and surrounding ocean in the depth range of 100–800 km. These maps derived from stochastic inversion of seismic surface-wave dispersion data, thermodynamic modeling of mantle mineral phase equilibria, and laboratory-based conductivity models. Because composition and temperature act as fundamental parameters, we obtain naturally scaled maps of shear-wave speed, density, and electrical conductivity that depend only on composition, physical conditions (pressure and temperature), and laboratory measurements of the conductivity of anhydrous mantle minerals. The maps show that in the upper mantle ρ,σ and VS follow the continental-tectonic division that separates the older central and western parts of Australia from the younger eastern part. The lithosphere beneath the central and western cratonic areas appears to be relatively cold and Fe-depleted, and this is reflected in fast shear-wave speeds, high densities, and low conductivities. In contrast, the lithosphere underneath younger regions is relatively hot and enriched with Fe, which is manifested in slow shear-wave speeds, low densities, and high conductivities. This trend appears to continue to depths well below 300 km. The slow-fast shear-wave speed distribution found here is also observed in independent seismic tomographic models of the Australian region, whereas the coupled slow-fast shear-wave speed, low-high density, and high-low electrical conductivity distribution has not been observed previously. Toward the bottom of the upper mantle at 400 km depth marking the olivine ⃗ wadsleyite transformation (the “410–km” seismic discontinuity), the correlation between VS, ρ, and σ weakens. In the transition zone, VS, ρ, and are much less correlated indicating a significant compositional contribution to lateral heterogeneity. In particular, in the lower transition zone, ρ and σ appear to be governed mostly by variations in Fe/(Fe + Mg), whereas lateral variations in VS result from changes in (Mg + Fe)/Si and not, as observed in the upper mantle, from temperature variations. Lower mantle lateral variations in thermochemical parameters appear to smooth out, which suggests a generally homogeneous lower mantle in agreement with seismic tomographic images of the lower mantle. As a test of the regional surface-wave-based conductivity model, we computed magnetic fields of 24 h Sqvariations and compared these to observations. The comparison shows that while our predicted conductivity model improves the fit to observations relative to a one-dimensional model, amplitudes of the computed conductivity anomalies appear not to be large enough to enable these to be discriminated at present.

KW - Electrical conductivity

KW - Electromagnetic sounding

KW - Mantle composition

KW - Mantle temperatures

KW - Phase equilibria

KW - Seismic wave-speed

KW - Surface waves

KW - Tomography

UR - http://www.scopus.com/inward/record.url?scp=84943778799&partnerID=8YFLogxK

U2 - 10.1007/978-3-319-15627-9_5

DO - 10.1007/978-3-319-15627-9_5

M3 - Book chapter

AN - SCOPUS:84943778799

SN - 9783319156262

SP - 145

EP - 171

BT - The Earth's Heterogeneous Mantle

PB - Springer

ER -

ID: 188757684