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PHYSICAL PROPERTIES of the EARTHS INTERIOR: ELECTRICAL CONDUCTIVITY

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Title: PHYSICAL PROPERTIES of the EARTHS INTERIOR: ELECTRICAL CONDUCTIVITY


1
PHYSICAL PROPERTIES of the EARTHS INTERIOR
ELECTRICAL CONDUCTIVITY
  • Electrical properties of rocks and minerals
  • Origin and characteristics of magnetotelluric
    fields and
  • telluric currents
  • Conductivity of the crust and upper mantle
  • Regional and local conductivity anomalies
  • Radial distribution of electrical conductivity

2
Electrical properties of minerals and rocks
  • Physical properties of rocks and minerals
  • Parameters Range
  • Densities gtgtgt small
  • Eastic wave velocities gtgtgt small
  • Radioactive content gtgtgt small
  • Magnetic susceptibility gtgtgt large 105
  • Electrical resistivity gtgtgt greatest
  • 10-5 ?m (dry coarse grained rocks) - 107 ?m
    (gabbro)

3
  • Electrical conduction
  • R Resistance, ohm (?) V Volt
  • I Amper
  • ? Resistivity (?m) ? Conductivity (1/ ?m
    or mho/m)
  • A m2 Siemens/mS/m
  • l m

4
  • Materials Conductivity (?)
  • Conductor ? gt 105 Sm-1
  • Large number of free electrons
  • Metals and graphite
  • Semiconductor 105 gt ? gt 10-8 Sm-1
  • Fewer mobile electrons
  • Insulator ? lt 10-8 Sm-1
  • Ionic bounding

5
  • Classification of materials based on the
    conductivity parameter (Schön,
  • 1998)
  • Metallic conductors
  • 2) Nonconductors
  • Insulators
  • Semiconductors
  • Electrolytes

6
  • Metallic conductors
  • Electrons are not tightly bounded or associated
    with any particular atom.
  • Electron conductivity ? Temperature ?
  • Native Copper, Silver, Gold
  • 10-8 ?m
  • Non conductors (Insulators Semiconductors
    Electrolytes)
  • Electrons are tightly trapped near atoms due to
    large energy barriers
  • between atoms.
  • Electron conductivity ? Temperature ?
  • Most rocks and Minerals

7
  • Insulators
  • Large energy barriers between atoms
  • Most silicates
  • 109-1017 ?m
  • Semiconductors
  • Energy barriers are slightly higher than the
    available energy from thermal activation at room
    temperature.
  • Most sulfides and oxides 10-6-104 ?m
  • Electrolytes
  • T (? Tcritical) ? Electrical conductivity ?
  • T (gt Tcritical) ? Electrical conductivity ?
  • Water 5x10-6 (pure) mho/m
  • Saturated water with salt in solution 102 mho/m
  • Mixture of these materials ? 10-8 1017 ?m

8
  • Electrical conduction in rocks and minerals
  • Metallic conduction (native metals copper, gold
    and graphite)
  • Electronic semiconduction (ilmenite, magnetite,
    pyrite and galena)
  • Electrolytic conduction
  • Solid electrolytes (ionic crystals) motions of
    ions
  • Most rock forming minerals act as solid
    electrolytes with the transfer of electric
    current being by motion of ions through a crystal
    lattice.
  • Electrolyte water solutions conductivity of
    pore water
  • In water-bearing rocks, the electrolyte
    conductivity of the pore water has dominant
    influence upon the rock conductivity.
  • The different kinds of electrical conduction have
    different temperature
  • dependencies.
  • Metallic conduction ? Temperature ?
    Conductivity ?
  • Semiconduction ? Temperature ? Conductivity ?

9
  • Resistivity of Minerals
  • Most rock-forming minerals (silicates and
    carbonates) have very high
  • specific resistivities ( gt 109 ?m). They are
    classified as insulators.
  • Conductive minerals (sulfides, some oxides and
    native elements) are
  • comparatively rare in the crust
  • Examples Resistivity (?m)
  • Native metals and their natural 10-8-10-5
  • paragenetic sequences
  • (graphite)
  • Native non metals 5x107-2.7x1016
  • (sulphur, selenium, diamond)
  • Anumber of sulfides, some oxides 10-6-1011

10
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11

12
  • Resistivity of rocks
  • (Schön, 1998)

13
  • Electrical properties of rocks
  • Dense, pore and fracture free rocks or absolutely
    dry rocks
  • Porous or fractured water bearing rocks
  • Porosity and fracturing ? ? Resistivity ?
  • Geological processes Their effects on
    resistivity (?)
  • Clay alteration ?
  • Dissolution ?
  • Faulting ?
  • Salt water intrusion ?
  • Shearing ?
  • Weathering ?
  • Carbonate perticipitation ?
  • Silification ?
  • Metamorphism ?
  • ?

14
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15
  • (Schön, 1998)

16
  • (Schön, 1998)

17
  • Induced Polarization
  • Electrode polarization
  • Polarization is attributed to the presence of
    interfaces between zones
  • of electronic and ionic conduction.
  • Pyrite
  • Membrane polarization
  • Polarization is attributed to the presence of
    interfaces between zones of
  • unequal ionic transport properties.
  • Clay
  • A few percent clay surface of silicate minerals

18
  • (Schön, 1998)

19
Origin and characteristics of magnetotelluric
field and telluric currents
  • Terrestrial Currents
  • T10 - 40 s
  • The current intensity is much larger on the
    daylight side of Earth as well as in aurora
    latitudes.
  • Electrical currents range 10 mV/km
  • Magnetic fields range milligamma
  • Random Fluctuations
  • Intensity electrical disturbances in the
    ionosphere f100 kHz
  • Electric storms (f ?) used in AFMAG methods
    (thunder storm energy)
  • Amplitude peaks at 8, 14 and 760 Hz

20
  • Audio and subaudio telluric and MT signals
  • Diurnal amplitude and azimuthal variations of
    telluric signals at
  • 1, 8, 145 and 3000 Hz
  • Amp. ? ? sunset
  • Amp. ? ? sunrise

21
  • (Telford et al., 1990)

22
  • Source I Periodic transient
    fluctuations
  • diurnal variations in the
    Earths
  • Magnetic field
  • Large scale (low f)
  • Source II Activities in Source I
  • influence the currents in
  • the ionosphere.
  • Magnetotelluric Fields (MT) penetrate
  • the Earths surface to produce
  • the telluric currents.
  • The telluric currents are induced
    in
  • the Earth by ionospheric
    currents.
  • (Telford et al., 1990)

23
  • Conductivity of the crust and upper mantle
  • Conductivity of rock unit
  • 1) Saline water in pores and cracks
  • 2) Conductive solid minerals
  • 3) High temperature
  • 4) Partial melts
  • or combination of these four factors (Meissner,
    1986)

24
  • Low conductivities unfractured crystalline
    rocks
  • Generally moisture (1), chemical composition (2)
    and temperature (3 and
  • 4) determine the conductivity in laboratory
    measurements.
  • Field measurements show shielding or disturbing
    effects of sedimentary
  • structures, edge effects and crustal influences.
  • Moho does not represent a generally occuring
    electromagnetic
  • discontinuity.

25
Regional and local conductivity anomalies
  • Methods used in the field investigation
    (Meissner, 1986)
  • Method 1 4 electrode resistivity-depth probing
    of the direct-current conduction method
  • Wide variety of direct-current techniques
  • Resistivity-depth profiles for horizontally
    stratified media to map the lateral
    inhomogeneties
  • The following Method 2 and 3 use the natural
    variations and pulsations (high frequency) of
    magnetic field of the Earth originating in the
    ionosphere
  • Observed electric (Ex, Ey, Ez) and magnetic (Hx,
    Hy, Hz) components on the Earths surface
    External origin other generated by induction

26
  • Method 2 The magnetotelluric method
  • Effective impedance
  • Apparent resistivity
  • ?a apparent resistivity
  • ?o permability of free space

27
  • Method 3 The magnetic array or magnetic
    gradient method or Wiese vector method
  • ?a(w) ? ?a(z)

28
  • Geomagnetic induction arrows (Wiese, 1965)
  • Hva HN b HE
  • If we combine the components of various signals
    to the same phase
  • Hv(to)aw HN(to) bw HE(to)
  • aw, bw determine the geomagnetic induction arrow
    in relation to the north direction.
  • tan?wbw/aw
  • For the time of the maximum of the vertical
    component, HV is chosen.

29
  • Method 4 The electromagnetic or controlled
    source magnetic induction method is widespread
    use by the mineral exploration industry.
  • Controlled source alternating currents (coil or
    long wire)
  • For crustal studies
  • Diameter of loop1.5 km
  • Recording (3-comp coils)100 km
  • Frequency 0.1 - 400 Hz
  • Apparent resistivity versus distance ? ? (z)
    models

30
  • (Meissner, 1986)

31
  • (Meissner, 1986)

32
  • (Meissner, 1986)

33
  • (Schön, 1998)

34
Radial distribution of electrical conductivity
  • For the conductivity down to 1500 km depth, use
    the short-period variations of the Earths
    magnetic field (less than a second several
    years)
  • T lt 1 year Outside solid Earth induced
    currents flowing in the crust and mantle
  • Diurnal variations interaction of conducting
    ionospheric layers of upper atmosphere with the
    main magnetic field solar wind and magnetic
    storms
  • Others
  • T27 days tides caused by the Moons orbital
    motion
  • T 1 year
  • T11 years sunspot cycle

35
  • The depth of penetration of an osciallation of
    period (T) above a uniform half-space of
    conductivity ? is
  • Period Penetration Depth
  • Tshort Shallow depth
  • Tlong Deeper
  • T1 s 1 year ? ? 1000-1500 km depth
  • ? 0-300 km depth (regional)

36
  • Steps of calculation
  • Data Vertical horizontal components of
    magnetic field (Diurnal and other variations T gt
    a few hours 300 1000 km)
  • Method
  • - Fourier analysis
  • Spherical harmonic variations 24, 12, 8 and 6
    hour
  • Spherical harmonic analysis were carried out on
    the world wide spread of data for each time of
    period to separate the internal and external
    parts of variation
  • - Amplitude ratio and phase differences between
    external and internal parts of each period of
    variation can be determined.
  • Use them to estimate conductivity distribution as
    a function of radius down to the depth of maximum
    penetration
  • For the calculation of conductivity in the lower
    mantle, use secular variations of the Earths
    magnetic field.

37
  • (Bott, 1982)

38
  • Silicate minerals like fayalite are insulators at
    room temperature.
  • Fayalite Fe2SiO4
  • T 770 K ? Fe2SiO4 ? Spinel phase transition
    (Semi conductors)
  • Impurity semi-conduction electronic
    semi-conduction ionic semi-conduction
  • Olivine (Fayalite)
  • Temperature
  • 900 K Impurity semi-conduction ? dominant
  • crust topmost mantle
  • 1000 K ? Electronic semi-conduction ? dominant
  • transition zone and lower mantle
  • 1400 K ? Ionic conductivity at low pressure ?
    dominant
  • upper mantle

39
  • (Bott, 1982)

40
  • Radial distribution of ? ? (Sm-1)
  • Ocean water logged sediments 4 10-3 - 1
  • Crystalline rocks of lithosphere 10-3
  • impurity semi conduction
  • Local anomalous regions
  • Stable continental regions 10-2 at 80 km
  • electronic semi conduction ? at deeper part
  • at higher temperature
  • Oceans 10-1 within small melt
    fraction asthenosphere
  • 300-700 km ? ? ?
  • temperature effect on
  • electronic and phase transition
  • 700 km 1
  • Bottom of mantle 100

41
REFERENCES
  • Bott, M.H.P., 1982, The Interior of the Earth
    its structure, constitution and
  • evolution, Elsevier, p 175-184 (ITU Mustafa Inan
    Library, QE 28.2.B68).
  • Meissner, R., 1986, The Continental Crust, A
    Geopysical Approach,
  • Academic Press, p 85-91.
  • Schön, J.H., 1998, Handbook of Geophysical
    Exploration, Seismic
  • Exploration, V 18 Physical Properties of rocks
    Fundamentals and Principles
  • of Petrophysics, Pergamon press, p 379-457 (ITU
    Mustafa Inan Library,
  • 431.6 P5 S34 1998).
  • Telford, W.M., Geldart, L.P., Sheriff, R. E.,
    1990, Applied Geophysics,
  • p 302-306 (ITU, Mustafa Inan Library).
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