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Earth's magnetic field


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The magnetosphere shields the surface of the Earth from the charged
particles of the solar wind and is generated by electric currents located
in many different parts of the Earth. It is compressed on the day (Sun)
side due to the force of the arriving particles, and extended on the night
side. (Image not to scale.)


The variation between magnetic north and "true" north.

*Earth's magnetic field* (and the *surface magnetic field*) is
approximately a magnetic dipole , with the magnetic field S pole near the
Earth 's geographic north pole (see Magnetic North Pole ) and the other
magnetic field N pole near the Earth's geographic south pole (see Magnetic
South Pole ). The cause of the field can be explained by dynamo theory .
Magnetic fields extend infinitely, though they are less densely grouped
further from their source. The Earth's magnetic field, which effectively
extends several tens of thousands of kilometres into space , is called the
magnetosphere . A paleomagnetic study of Australian red dacite and pillow
basalt has estimated the magnetic field to be at least 3.5 billion years
old.^[1] ^[2]


Contents

[hide ]

* 1 Importance 
* 2 Magnetic pole 
* 3 Field characteristics 
* 4 Magnetic field variations 
* 5 Magnetic field reversals 
* 6 Magnetic field detection 
* 7 See also 
* 8 Notes 
* 9 References 
* 10 Further reading 
* 11 External links 


[edit ] Importance

See also: Solar wind

Earth itself is largely protected from the solar wind , a stream of
energetic charged particles emanating from the Sun , by its magnetic field
which deflects most of the charged particles. Some of the charged
particles from the solar wind are /trapped/ in the Van Allen radiation
belt . A smaller number of particles from the solar wind manage to travel,
as though on an electromagnetic energy transmission line, to the Earth's
upper atmosphere and ionosphere in the auroral zones. The only time the
solar wind is observable on the Earth is when it is strong enough to
produce phenomena such as the aurora and geomagnetic storms . Bright
auroras strongly heat the ionosphere, causing its plasma to expand into
the magnetosphere , increasing the size of the plasma geosphere , and
causing escape of atmospheric matter into the solar wind. Geomagnetic
storms result when the pressure of plasmas contained inside the
magnetosphere is sufficiently large to inflate and thereby distort the
geomagnetic field.

The solar wind is responsible for the overall shape of Earth's
magnetosphere, and fluctuations in its speed, density, direction, and
entrained magnetic field strongly affect Earth's local space environment.
For example, the levels of ionizing radiation and radio interference can
vary by factors of hundreds to thousands; and the shape and location of
the magnetopause and bow shock wave upstream of it can change by several
Earth radii, exposing geosynchronous satellites to the direct solar wind.
These phenomena are collectively called space weather . The mechanism of
atmospheric stripping is caused by gas being caught in bubbles of magnetic
field, which are ripped off by solar winds.^[3] Variations in the magnetic
field strength have been correlated to rainfall variation within the
tropics .^[4]


[edit ] Magnetic pole



Simulation of the interaction between Earth's magnetic field and the
interplanetary magnetic field. Main articles: North Magnetic Pole and
South Magnetic Pole


Magnetic declination from true north in 2000.


Magnetic declination from true north in 1700

Two different types of magnetic poles must be distinguished. There are the
"magnetic poles" and the "geomagnetic poles ". The magnetic poles are the
two positions on the Earth's surface where the magnetic field is entirely
vertical. Another way of saying this is that the inclination of the
Earth's field is 90° at the North Magnetic Pole and -90° at the South
Magnetic Pole. At either the South or North Magnetic Poles, a typical
compass that is allowed to swing only in the horizontal plane will point
in random directions. The Earth's field is closely approximated by the
field of a dipole positioned near the centre of the Earth. A dipole
defines an axis. The two positions where the axis of the dipole that best
fits the Earth's field intersect the Earth's surface are called the North
and South geomagnetic poles. If the Earth's field were perfectly dipolar,
the geomagnetic and magnetic poles would coincide. However, there are
significant non-dipolar terms which cause the position of the two types of
poles to be in different places.

The locations of the magnetic poles are not static; they wander as much as
15 km every year (Dr. David P. Stern, emeritus Goddard Space Flight
Center, NASA ^[/citation needed /] ). The pole position is usually not
that which is indicated on many charts. The /Geomagnetic Pole/ positions
are usually not close to the position that commercial cartographers place
"Magnetic Poles." "Geomagnetic Dipole Poles", "IGRF Model Dip Poles", and
"Magnetic Dip Poles" are variously used to denote the magnetic poles.^[5]
The Earth's field changes in strength and position. The two poles wander
independently of each other and are not at directly opposite positions on
the globe. Currently the magnetic south pole is farther from the
geographic south pole than the magnetic north pole is from the geographic
north pole.

Magnetic pole positions North Magnetic Pole^[6] (2001) 81°18′N
110°48′W / 81.3°N 110.8°W / 81.3; -110.8 (North Magnetic Pole (2001))

	(2004 est) 82°18′N 113°24′W / 82.3°N 113.4°W / 82.3;
-113.4 (North Magnetic Pole (2004))

	(2005 est) 82°42′N 114°24′W / 82.7°N 114.4°W / 82.7;
-114.4 (North Magnetic Pole (2005))


South Magnetic Pole^[7] (1998) 64°36′S 138°30′E / 64.6°S 138.5°E /
-64.6; 138.5 (South Magnetic Pole (1998))

	(2004 est) 63°30′S 138°00′E / 63.5°S 138.0°E / -63.5;
138.0 (South Magnetic Pole (2004))

	(2005 est)63°06′S 137°30′E / 63.1°S 137.5°E / -63.1; 137.5
(South Magnetic Pole (2005))




[edit ] Field characteristics

The strength of the field at the Earth's surface ranges from less than 30
microteslas (0.3 gauss)  in an area including most of South America and
South Africa to over 60 microteslas (0.6 gauss)  around the magnetic poles
in northern Canada and south of Australia, and in part of Siberia.

The field is similar to that of a bar magnet . The Earth's magnetic field
is mostly caused by electric currents in the liquid outer core. The
Earth's core is hotter than 1043 K , the Curie point temperature above
which the orientations of spins within iron become randomized. Such
randomization causes the substance to lose its magnetization.

Convection of molten iron within the outer liquid core, along with a
Coriolis effect caused by the overall planetary rotation, tends to
organize these "electric currents" in rolls aligned along the north-south
polar axis. When conducting fluid flows across an existing magnetic field,
electric currents are induced, which in turn creates another magnetic
field. When this magnetic field reinforces the original magnetic field, a
dynamo is created which sustains itself. This is called the Dynamo Theory
and it explains how the Earth's magnetic field is sustained.

Another feature that distinguishes the Earth magnetically from a bar
magnet is its magnetosphere . At large distances from the planet, this
dominates the surface magnetic field. Electric currents induced in the
ionosphere also generate magnetic fields. Such a field is always generated
near where the atmosphere is closest to the Sun, causing daily alterations
which can deflect surface magnetic fields by as much as one degree.
Typical daily variations of field strength are about 25 nanoteslas (nT)
(i.e. ~ 1:2,000), with variations over a few seconds of typically around 1
nT (i.e. ~ 1:50,000).^[8]


[edit ] Magnetic field variations



Geomagnetic variations since last reversal.

The currents in the core of the Earth that create its magnetic field
started up at least 3,450

million years ago.^[9] ^[10]

Magnetometers detect minute deviations in the Earth's magnetic field
caused by iron artifacts , kilns, some types of stone structures, and even
ditches and middens in archaeological geophysics . Using magnetic
instruments adapted from airborne magnetic anomaly detectors developed
during World War II to detect submarines, the magnetic variations across
the ocean floor have been mapped. The basalt — the iron-rich, volcanic
rock making up the ocean floor — contains a strongly magnetic mineral
(magnetite ) and can locally distort compass readings. The distortion was
recognized by Icelandic mariners as early as the late 18th century. More
important, because the presence of magnetite gives the basalt measurable
magnetic properties, these magnetic variations have provided another means
to study the deep ocean floor. When newly formed rock cools, such magnetic
materials record the Earth's magnetic field.

Frequently, the Earth's magnetosphere is hit by solar flares causing
geomagnetic storms , provoking displays of aurorae . The short-term
instability of the magnetic field is measured with the K-index .

Recently, leaks have been detected in the magnetic field, which interact
with the Sun's solar wind in a manner opposite to the original hypothesis.
During solar storms , this could result in large-scale blackouts and
disruptions in artificial satellites .^[11]

/See also Magnetic anomaly , South Atlantic Anomaly /


[edit ] Magnetic field reversals

Main article: Geomagnetic reversal

Based upon the study of lava flows of basalt throughout the world, it has
been proposed that the Earth's magnetic field reverses at intervals,
ranging from tens of thousands to many millions of years , with an average
interval of approximately 300,000 years.^[12] However, the last such
event, called the Brunhes–Matuyama reversal , is observed to have
occurred some 780,000 years ago.

There is no clear theory as to how the geomagnetic reversals might have
occurred . Some scientists have produced models for the core of the Earth
wherein the magnetic field is only quasi-stable and the poles can
spontaneously migrate from one orientation to the other over the course of
a few hundred to a few thousand years. Other scientists propose that the
geodynamo first turns itself off, either spontaneously or through some
external action like a comet impact , and then restarts itself with the
magnetic "North" pole pointing either North or South. External events are
not likely to be routine causes of magnetic field reversals due to the
lack of a correlation between the age of impact craters and the timing of
reversals. Regardless of the cause, when the magnetic pole flips from one
hemisphere to the other this is known as a reversal, whereas temporary
dipole tilt variations that take the dipole axis across the equator and
then back to the original polarity are known as excursions.

Studies of lava flows on Steens Mountain , Oregon, indicate that the
magnetic field could have shifted at a rate of up to 6 degrees per day at
some time in Earth's history, which significantly challenges the popular
understanding of how the Earth's magnetic field works.^[13]

Paleomagnetic studies such as these typically consist of measurements of
the remnant magnetization of igneous rock from volcanic events. Sediments
laid on the ocean floor orient themselves with the local magnetic field, a
signal which can then be recorded as they solidify. Although deposits of
igneous rock are mostly paramagnetic , they do contain traces of ferri -
and antiferromagnetic materials in the form of ferrous oxides, thus giving
them the ability to possess remnant magnetization. In fact, this
characteristic is quite common in numerous other types of rocks and
sediments found throughout the world. One of the most common of these
oxides found in natural rock deposits is magnetite .

As an example of how this property of igneous rocks allows us to determine
that the Earth's field has reversed in the past, consider measurements of
magnetism across ocean ridges . Before magma exits the mantle through a
fissure, it is at an extremely high temperature, above the Curie
temperature of any ferrous oxide that it may contain. The lava begins to
cool and solidify once it enters the ocean, allowing these ferrous oxides
to eventually regain their magnetic properties, specifically, the ability
to hold a remnant magnetization. Assuming that the only magnetic field
present at these locations is that associated with the Earth itself, this
solidified rock will become magnetized in the direction of the geomagnetic
field. Although the strength of the field is rather weak and the iron
content of typical rock samples is small, the relatively small remnant
magnetization of the samples is well within the resolution of modern
magnetometers . The age and magnetization of solidified lava samples can
then be measured to determine the orientation of the geomagnetic field
during ancient eras.


[edit ] Magnetic field detection



Deviations of a magnetic field model from measured data, data created by
satellites with sensitive magnetometers

The Earth's magnetic field strength was measured by Carl Friedrich Gauss
in 1835 and has been repeatedly measured since then, showing a relative
decay of about 10% over the last 150 years ^[14] The Magsat satellite and
later satellites have used 3-axis vector magnetometers to probe the 3-D
structure of the Earth's magnetic field. The later Ørsted satellite
allowed a comparison indicating a dynamic geodynamo in action that appears
to be giving rise to an alternate pole under the Atlantic Ocean west of S.
Africa.^[15]


Governments sometimes operate units which specialise in the measurement of
the Earth 's magnetic field. These are geomagnetic observatories ,
typically part of a national Geological Survey , for example the British
Geological Survey 's Eskdalemuir Observatory . Such observatories can
measure and forecast magnetic conditions which can sometimes affect
communications, electric power and other human activities; see magnetic
storm .

The military can take a keen interest in determining the characteristics
of the local geomagnetic field, in order to detect /anomalies/ in the
natural background, which might be caused by the presence of a significant
metallic object such as a submerged submarine. Typically, these magnetic
anomaly detectors are flown in aircraft like the UK 's Nimrod or towed as
an instrument or an array of instruments from surface ships.

Commercially, geophysical prospecting companies also use magnetic
detectors to identify naturally occurring anomalies from ore bodies, such
as the Kursk Magnetic Anomaly .

Animals including birds and turtles can detect the Earth's magnetic field,
and use the field to navigate during migration .^[16] Cows and wild deer
tend to align their bodies north-south while relaxing, but not when the
animals are under high voltage power lines, leading researchers to believe
magnetism is responsible.^[17] ^[18]


Seismo-electromagnetics is an area of research aimed at earthquake
prediction.


[edit ] See also

* Auroral kilometric radiation (AKR) * Dip circle * Earth battery * Earth
potential rise * Geomagnetic jerk * Dipole model of the Earth's magnetic
field

* L-shell * Magnetic declination * Magnetic field of celestial bodies

* Magnetosphere of Jupiter * Van Allen radiation belt * Voyages of
Christopher Columbus


Global evolution/anomaly of the Earth's magnetic field: [1] sweeps are in
10 degree steps at 10 years intervals. based on data from:The Institute of
Geophysics, ETH Zurich


[edit ] Notes

1. *^ * T. N. W. McElhinney and W. E. Senanayake , J. Geophys. Res. 85,
3523 (1980). 2. *^ * B. A. Buffett. Earth's Core and the Geodynamo.
Science, vol. 288 (5473), 2000, pp. 2007 - 2012. DOI:
10.1126/science.288.5473.2007. 3. *^ * Cosmos Online - Solar wind ripping
chunks off Mars
(http://www.cosmosmagazine.com/news/2369/solar-wind-ripping-chunks-mars)
4. *^ * AFP (2009-01-13). "Earth's Magnetic Field Changes Climate" .
Discovery News.
http://dsc.discovery.com/news/2009/01/13/magnetic-field-climate.html.
Retrieved 2010-02-24.  5. *^ * "/Problem with the "MAGNETIC" Pole
Locations on Global Charts /". Eos Vol. 77, No. 36, American Geophysical
Union, 1996. 6. *^ * Geomagnetism, North Magnetic Pole . Natural Resources
Canada, 2005-03-13. 7. *^ * South Magnetic Pole . Commonwealth of
Australia, Australian Antarctic Division, 2002. 8. *^ * Nature, Vol 439
(16 Feb 2006) 9. *^ * Usui, Y.; Tarduno, J. A.; Watkeys, M.; Hofmann, A.;
Cottrell, R. D. (2009). "Evidence for a 3.45-billion-year-old magnetic
remanence: Hints of an ancient geodynamo from conglomerates of South
Africa". /Geochemistry Geophysics Geosystems/ *10*: Q09Z07. doi
:10.1029/2009GC002496 .  edit

10. *^ * Tarduno, J. A.; Cottrell, R. D.; Watkeys, M. K.;
Hofmann, A.; Doubrovine, P. V.; Mamajek, E. E.; Liu, D.; Sibeck,
D. G. /et al/. (2010). "Geodynamo, Solar Wind, and Magnetopause
3.4 to 3.45 Billion Years Ago". /Science/ *327* (5970): 1238. doi
:10.1126/science.1183445
. PMID
20203044
.  edit

11. *^ * Thompson, Andrea (December 16, 2008). "Leaks
Found in Earth's Protective Magnetic Shield"
.
/Space.com/. Imaginova Corp..
http://www.space.com/scienceastronomy/081216-agu-solar-storm-shield-break.html.
Retrieved 2009-03-28. 
12. *^ * Phillips, Tony (December 29, 2003). "Earth's
Inconstant Magnetic Field"
.
/Science@Nasa/.
http://science.nasa.gov/headlines/Y2003/29dec_magneticfield.htm.
Retrieved December 27, 2009. 
13. *^ * Coe, R. S.; Prévot, M.; Camps, P. (20 April
2002). "New evidence for extraordinarily rapid change of the
geomagnetic field during a reversal"
.
/Nature/ *374*: 687. doi
:10.1038/374687a0
.
http://www.nature.com/nature/journal/v374/n6524/abs/374687a0.html. 
14. *^ * Annual Review of Earth and Planetary Science,
1988 16 p.435 "Time Variations of the Earth's Magnetic Field: From
Daily to Secular" by Vincent Courtillot 
and Jean Louis Le Mouel
15. *^ * Hulot G, Eymin C, Langlais B,
Mandea M, Olsen N (April 2002). "Small-scale structure of the
geodynamo inferred from Oersted and Magsat satellite data".
/Nature/ *416* (6881): 620–3. doi
:10.1038/416620a
. PMID
11948347
. 
16. *^ * Deutschlander M, Phillips J, Borland S (1999)
"The case for light-dependent magnetic orientation in animals"
/Journal of Experimental Biology/ *202*(8): 891-908
17. *^ * Burda, H; Begall, S; Cerveny, J;
Neef, J; Nemec, P (Mar 2009). "Extremely low-frequency
electromagnetic fields disrupt magnetic alignment of ruminants."
.
/Proceedings of the National Academy of Sciences of the United
States of America/ *106* (14): 5708–13. doi
:10.1073/pnas.0811194106
. PMID
19299504
. 
18. *^ * Dyson, PJ (2009). "Biology:
Electric cows". /Nature/ *458* (7237): 389. doi
:10.1038/458389a
. PMID
19325587
.