5. Evidence for Plate Tectonics from Magnetics William Wilcock OCEAN/ESS 410
Dec 16, 2015
Lecture/Lab Learning Goals
• Understand the basic characteristics of the Earth’s magnetic field and how one measures its orientation
• Know the different kinds of rock magnetization and their use in paleomagnetism
• Be able to explain the historical concept of polar wander and its explanation in terms of continental drift
• Be able to explain patterns of marine magnetic anomalies in terms of plate spreading and magnetic field reversals
• Know how to interpret marine magnetic anomalies - LAB
south pole
south pole
north pole
Geodynamo Theory: The magnetic field is generated in the liquid metal region of the outer core. The outer core is extremely hot and flows at a rate of several km/yr in large convection currents. Convecting metal (Fe) creates electrical currents, which in turn create the magnetic field.
Geographic north pole
Geographic south Pole
Magnetic south
Magnetic north
After Plummer
The Earth is surrounded by a magnetic field that is strongest near the poles. The magnetic poles are displaced ~ 11.5° from the geographic poles about which the Earth rotates.
Earth’s Magnetic Field
Earth’s Magnetic Field•The Earth’s magnetic field close to a dipole. The radial (vertical) and tangential (north-south) components a dipole field are given by
θ - Colatitude (0º at south pole; 90º at equator; 180º at north pole
μ0 - magnetic permeability of a vacuum 4π x 10-7 N A-2
r - distance to the center of the earth (6.4 x 106 m at the Earth’s surface)
M - is the dipole moment which for the earth is 7.95 x 1022 A m2
B - is the magnetic field. It units are Teslas 1 T = 1 kg A-1 s-2. 1 nT = 10-9 T = 1 Gamma
Earth’s Magnetic Field
Field is twice as strong at the poles as at the equator. About 60,000 γ at poles and 30,000 γ at equator
From The way the Earth Works by P. J. Wyllie, Wiley 1976
Measuring the Orientation of the Earth’s Magnetic Field
D
From The way the Earth Works by P. J. Wyllie, Wiley 1976
I
D = Declination (angle from geographic north)
I = Inclination (dip angle)
Measurements of the Earths Magnetic Field in the Oceans
Measurements of the Earth’s magnetic field in the oceans were developed in the 2nd World War as a way to detect submarines (and later mines)
Measurements of the magnetic field were first made with a fluxgate magnetometer. Such instruments are still in use today
Rock Magnetization• Most minerals either repel or concentrate the Earth’s
magnetic field lines but do not themselves become magnetized.
• A few ferromagnetic minerals retain magnetization. In the oceanic crust the most important is magnetite (Fe3O4). Others include ilmenite (FeTiO3), hematite (Fe2O3), and pyrrhotite (FeS).
• Forms of rock magnetism– Thermo remnant magnetism - rock becomes
magnetized when it cools below the Currie temperature (580°C) in a magnetic field
– Detrital remnant magnetism - sediments settle in a magnetic field
– Chemical remnant magnetism - Hematite precipitates from a fluid circulating through a rock.
PaleomagnetismIn the 1950’s scientists learned how to measure the remnant magnetism of rock samples. If one can be sure that the rock has not been rotated by tectonic processes then:
•The Declination of the remnant magnetism gives the apparent direction of the North Pole at the time the rock formed.
•The Inclination gives the latitude of the rock when it formed
Geochronology
In the 1950’s scientists also developed reliable techniques of dating rocks using radioactive isotopes
The potassium isotope 40K decays to 40Ar with a half-life of 1.3x109 years. As argon is a gas any traces of that element will escape from rocks when they are molten. Therefore, any argon found in solid rocks must have been produced since that molten state ended and the rock solidified. The ratio of 40K to 40Ar can be analyzed and a numerical date since the last molten state can be assigned.
By combining paleomagnetic data from lava flows with the lava ages, scientists were able to look at changes in the apparent position of the Earth’s magnetic pole with time.
“Polar Wander”
(a) Position of the North pole relative to Europe and Asia
(b) Position of the North pole relative to Eurasia and North America
Opening of the Atlantic
http://museum.gov.ns.ca/fossils/geol/globe.htm
Polar Wander and Continental Drift
K - 100 Myr; Tru - 200 Myr; Cu - 300 Myr; € - 500 Myr
(a) Polar wander for North America and Eurasia
(b) Polar wander corrected for the opening of the Atlantic
Evidence for Continental Drift - pre1960’sEvidence• Fit of the Atlantic Coastlines and Geology• Paleontology (Fossils)• Paleoclimate• Paleomagnetism
Why wasn’t this evidence accepted?• Physical impossibility of drift (the mantle is solid - it
transmits seismic waves)• Difficulties of magnetic measurements - scatter,
reversals• Conservatism
The mechanism of polarity reversals is poorly understood but they happen quickly (within no more than ~1000 years)
Polarity Reversals
Using volcanic rocks to develop a polarity timescale
Most geoscientists were initially skeptical of magnetic reversals but interest increased once it was realized that they provided a means to date events
Polarity timescale from magnetized lava flows
The first timescales were obtained in the early 1960’s
History of Polarity Reversals
Cretaceous Quiet Zone
Jurassic Quiet Zone (a period of very rapid reversals?)
Marine magnetic anomaliesThe magnetization of the oceanic crust leads to small variations in the intensity of the magnetic field measured at the sea surface
Marine Magnetic AnomaliesIf we remove the background Earth’s magnetic field from the total magnetic intensity, we obtain the magnetic anomaly
Normally magnetized crust
Magma
dikesoceanic crust
Reversely magnetized crust
Normally magnetizedcrust
N
N
N
N
NN
Magma
Magma
Vine and Matthews’ Magnetic Tape Recorder
Eas
t Pac
ific
Ris
e
Mid-A
tlantic Ridge
Map shown in next slide
Global bathymetry, showing ocean ridge system
Ship track across the East Pacific Rise which obtained the magnetic anomaly profile shown in the next slide. The measurements were made in the 1960’s by the Columbia University research vessel Eltanin.
19
Location of the Eltanin-19 profile
The vertical scale for total intensity anomaly is shown in “gammas”. This is the same as nanoTeslas or nT. The horizontal lines are at zero anomaly; the scale is thus minus 500 to plus 500 nT.
Ocean depth, km
Magnetic anomaly, gamma
Eltanin 19 Magnetic Anomaly Profile
ESEWNW
WNWESE
measured profile of total intensity anomaliesmirror image of measured
profile to show symmetry
Symmetry of the Eltanin 19 profile