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Geomagnetic reversal

January 01, 1970

"Magnetic reversal" redirects here. For switching of a magnet, see Magnetization reversal.
"Polarity reversal" redirects here. For a seismic anomaly, see Polarity reversal (seismology).

A geomagnetic reversal is a change in a planet's magnetic field such that the positions of magnetic north and magnetic south are interchanged (not to be confused with geographic north and geographic south). The Earth's field has alternated between periods of normal polarity, in which the predominant direction of the field was the same as the present direction, and reverse polarity, in which it was the opposite. These periods are called chrons.

Geomagnetic polarity during the last 5 million years (Pliocene and Quaternary, late Cenozoic Era). Dark areas denote periods where the polarity matches today's normal polarity; light areas denote periods where that polarity is reversed.

Reversal occurrences are statistically random. There have been at least 183 reversals over the last 83 million years (on average once every ~450,000 years). The latest, the Brunhes–Matuyama reversal, occurred 780,000 years ago[1] with widely varying estimates of how quickly it happened. Other sources estimate that the time that it takes for a reversal to complete is on average around 7,000 years for the four most recent reversals.[2] Clement (2004) suggests that this duration is dependent on latitude, with shorter durations at low latitudes and longer durations at mid and high latitudes.[2] Although variable, the duration of a full reversal is typically between 2,000 and 12,000 years.[3]

Although there have been periods in which the field reversed globally (such as the Laschamp excursion) for several hundred years,[4] these events are classified as excursions rather than full geomagnetic reversals. Stable polarity chrons often show large, rapid directional excursions, which occur more often than reversals, and could be seen as failed reversals. During such an excursion, the field reverses in the liquid outer core but not in the solid inner core. Diffusion in the outer core is on timescales of 500 years or less while that of the inner core is longer, around 3,000 years.[5]

History edit

In the early 20th century, geologists such as Bernard Brunhes first noticed that some volcanic rocks were magnetized opposite to the direction of the local Earth's field. The first systematic evidence for and time-scale estimate of the magnetic reversals were made by Motonori Matuyama in the late 1920s; he observed that rocks with reversed fields were all of early Pleistocene age or older. At the time, the Earth's polarity was poorly understood, and the possibility of reversal aroused little interest.[6][7]

Three decades later, when Earth's magnetic field was better understood, theories were advanced suggesting that the Earth's field might have reversed in the remote past. Most paleomagnetic research in the late 1950s included an examination of the wandering of the poles and continental drift. Although it was discovered that some rocks would reverse their magnetic field while cooling, it became apparent that most magnetized volcanic rocks preserved traces of the Earth's magnetic field at the time the rocks had cooled. In the absence of reliable methods for obtaining absolute ages for rocks, it was thought that reversals occurred approximately every million years.[6][7]

The next major advance in understanding reversals came when techniques for radiometric dating were improved in the 1950s. Allan Cox and Richard Doell, at the United States Geological Survey, wanted to know whether reversals occurred at regular intervals, and they invited geochronologist Brent Dalrymple to join their group. They produced the first magnetic-polarity time scale in 1959. As they accumulated data, they continued to refine this scale in competition with Don Tarling and Ian McDougall at the Australian National University. A group led by Neil Opdyke at the Lamont–Doherty Earth Observatory showed that the same pattern of reversals was recorded in sediments from deep-sea cores.[7]

During the 1950s and 1960s information about variations in the Earth's magnetic field was gathered largely by means of research vessels, but the complex routes of ocean cruises rendered the association of navigational data with magnetometer readings difficult. Only when data were plotted on a map did it become apparent that remarkably regular and continuous magnetic stripes appeared on the ocean floors.[6][7]

 

In 1963, Frederick Vine and Drummond Matthews provided a simple explanation by combining the seafloor spreading theory of Harry Hess with the known time scale of reversals: sea floor rock is magnetized in the direction of the field when it is formed. Thus, sea floor spreading from a central ridge will produce pairs of magnetic stripes parallel to the ridge.[8] Canadian L. W. Morley independently proposed a similar explanation in January 1963, but his work was rejected by the scientific journals Nature and Journal of Geophysical Research, and remained unpublished until 1967, when it appeared in the literary magazine Saturday Review.[6] The Morley–Vine–Matthews hypothesis was the first key scientific test of the seafloor spreading theory of continental drift.[7]

Past field reversals are recorded in the solidified ferrimagnetic minerals of consolidated sedimentary deposits or cooled volcanic flows on land. Beginning in 1966, Lamont–Doherty Geological Observatory scientists found that the magnetic profiles across the Pacific-Antarctic Ridge were symmetrical and matched the pattern in the north Atlantic's Reykjanes ridge. The same magnetic anomalies were found over most of the world's oceans, which permitted estimates for when most of the oceanic crust had developed.[6][7]

Observing past fields edit

 
Geomagnetic polarity since the middle Jurassic. Dark areas denote periods where the polarity matches today's polarity, while light areas denote periods where that polarity is reversed. The Cretaceous Normal superchron is visible as the broad, uninterrupted black band near the middle of the image.

Because no existing unsubducted sea floor (or sea floor thrust onto continental plates) is more than about 180 million years (Ma) old, other methods are necessary for detecting older reversals. Most sedimentary rocks incorporate minute amounts of iron-rich minerals, whose orientation is influenced by the ambient magnetic field at the time at which they formed. These rocks can preserve a record of the field if it is not later erased by chemical, physical or biological change.

Because Earth's magnetic field is a global phenomenon, similar patterns of magnetic variations at different sites may be used to help calculate age in different locations. The past four decades of paleomagnetic data about seafloor ages (up to ~250 Ma) has been useful in estimating the age of geologic sections elsewhere. While not an independent dating method, it depends on "absolute" age dating methods like radioisotopic systems to derive numeric ages. It has become especially useful when studying metamorphic and igneous rock formations where index fossils are seldom available.

Geomagnetic polarity time scale edit

Further information: Magnetostratigraphy

Through analysis of seafloor magnetic anomalies and dating of reversal sequences on land, paleomagnetists have been developing a Geomagnetic Polarity Time Scale. The current time scale contains 184 polarity intervals in the last 83 million years (and therefore 183 reversals).[9][10]

Changing frequency over time edit

The rate of reversals in the Earth's magnetic field has varied widely over time. Around 72 Ma, the field reversed 5 times in a million years. In a 4-million-year period centered on 54 Ma, there were 10 reversals; at around 42 Ma, 17 reversals took place in the span of 3 million years. In a period of 3 million years centering on 24 Ma, 13 reversals occurred. No fewer than 51 reversals occurred in a 12-million-year period, centering on 15 Ma. Two reversals occurred during a span of 50,000 years. These eras of frequent reversals have been counterbalanced by a few "superchrons:" long periods when no reversals took place.[11]

Superchrons edit

A superchron is a polarity interval lasting at least 10 million years. There are two well-established superchrons, the Cretaceous Normal and the Kiaman. A third candidate, the Moyero, is more controversial. The Jurassic Quiet Zone in ocean magnetic anomalies was once thought to represent a superchron but is now attributed to other causes.

The Cretaceous Normal (also called the Cretaceous Superchron or C34) lasted for almost 40 million years, from about 120 to 83 million years ago, including stages of the Cretaceous period from the Aptian through the Santonian. The frequency of magnetic reversals steadily decreased prior to the period, reaching its low point (no reversals) during the period. Between the Cretaceous Normal and the present, the frequency has generally increased slowly.[12]

The Kiaman Reverse Superchron lasted from approximately the late Carboniferous to the late Permian, or for more than 50 million years, from around 312 to 262 million years ago.[12] The magnetic field had reversed polarity. The name "Kiaman" derives from the Australian town of Kiama, where some of the first geological evidence of the superchron was found in 1925.[13]

The Ordovician is suspected to have hosted another superchron, called the Moyero Reverse Superchron, lasting more than 20 million years (485 to 463 million years ago). Thus far, this possible superchron has only been found in the Moyero river section north of the polar circle in Siberia.[14] Moreover, the best data from elsewhere in the world do not show evidence for this superchron.[15] Certain regions of ocean floor, older than 160 Ma, have low-amplitude magnetic anomalies that are hard to interpret. They are found off the east coast of North America, the northwest coast of Africa, and the western Pacific. They were once thought to represent a superchron called the Jurassic Quiet Zone, but magnetic anomalies are found on land during this period. The geomagnetic field is known to have low intensity between about 130 Ma and 170 Ma, and these sections of ocean floor are especially deep, causing the geomagnetic signal to be attenuated between the seabed and the surface.[15]

Statistical properties edit

Several studies have analyzed the statistical properties of reversals in the hope of learning something about their underlying mechanism. The discriminating power of statistical tests is limited by the small number of polarity intervals. Nevertheless, some general features are well established. In particular, the pattern of reversals is random. There is no correlation between the lengths of polarity intervals.[16] There is no preference for either normal or reversed polarity, and no statistical difference between the distributions of these polarities. This lack of bias is also a robust prediction of dynamo theory.[12]

There is no rate of reversals, as they are statistically random. The randomness of the reversals is inconsistent with periodicity, but several authors have claimed to find periodicity.[17] However, these results are probably artifacts of an analysis using sliding windows to attempt to determine reversal rates.[18]

Most statistical models of reversals have analyzed them in terms of a Poisson process or other kinds of renewal process. A Poisson process would have, on average, a constant reversal rate, so it is common to use a non-stationary Poisson process. However, compared to a Poisson process, there is a reduced probability of reversal for tens of thousands of years after a reversal. This could be due to an inhibition in the underlying mechanism, or it could just mean that some shorter polarity intervals have been missed.[12] A random reversal pattern with inhibition can be represented by a gamma process. In 2006, a team of physicists at the University of Calabria found that the reversals also conform to a Lévy distribution, which describes stochastic processes with long-ranging correlations between events in time.[19][20] The data are also consistent with a deterministic, but chaotic, process.[21]

Character of transitions edit

Duration edit

Most estimates for the duration of a polarity transition are between 1,000 and 10,000 years,[12] but some estimates are as quick as a human lifetime.[22] During a transition, the magnetic field will not vanish completely, but many poles might form chaotically in different places during reversal, until it stabilizes again.[23][24]

Studies of 16.7-million-year-old lava flows on Steens Mountain, Oregon, indicate that the Earth's magnetic field is capable of shifting at a rate of up to 6 degrees per day.[25] This was initially met with skepticism from paleomagnetists. Even if changes occur that quickly in the core, the mantle—which is a semiconductor—is thought to remove variations with periods less than a few months. A variety of possible rock magnetic mechanisms were proposed that would lead to a false signal.[26] That said, paleomagnetic studies of other sections from the same region (the Oregon Plateau flood basalts) give consistent results.[27][28] It appears that the reversed-to-normal polarity transition that marks the end of Chron C5Cr (16.7 million years ago) contains a series of reversals and excursions.[29] In addition, geologists Scott Bogue of Occidental College and Jonathan Glen of the US Geological Survey, sampling lava flows in Battle Mountain, Nevada, found evidence for a brief, several-year-long interval during a reversal when the field direction changed by over 50 degrees. The reversal was dated to approximately 15 million years ago.[30][31] In 2018, researchers reported a reversal lasting only 200 years.[32] A 2019 paper estimates that the most recent reversal, 780,000 years ago, lasted 22,000 years.[33][34]

Causes edit

 
NASA computer simulation using the model of Glatzmaier and Roberts.[35] The tubes represent magnetic field lines, blue when the field points towards the center and yellow when away. The rotation axis of the Earth is centered and vertical. The dense clusters of lines are within the Earth's core.[24]

The magnetic field of the Earth, and of other planets that have magnetic fields, is generated by dynamo action in which convection of molten iron in the planetary core generates electric currents which in turn give rise to magnetic fields.[12] In simulations of planetary dynamos, reversals often emerge spontaneously from the underlying dynamics. For example, Gary Glatzmaier and collaborator Paul Roberts of UCLA ran a numerical model of the coupling between electromagnetism and fluid dynamics in the Earth's interior. Their simulation reproduced key features of the magnetic field over more than 40,000 years of simulated time, and the computer-generated field reversed itself.[35][36] Global field reversals at irregular intervals have also been observed in the laboratory liquid metal experiment "VKS2".[37]

In some simulations, this leads to an instability in which the magnetic field spontaneously flips over into the opposite orientation. This scenario is supported by observations of the solar magnetic field, which undergoes spontaneous reversals every 9–12 years. With the Sun it is observed that the solar magnetic intensity greatly increases during a reversal, whereas reversals on Earth seem to occur during periods of low field strength.[38]

Some scientists, such as Richard A. Muller, think that geomagnetic reversals are not spontaneous processes but rather are triggered by external events that directly disrupt the flow in the Earth's core. Proposals include impact events[39][40] or internal events such as the arrival of continental slabs carried down into the mantle by the action of plate tectonics at subduction zones or the initiation of new mantle plumes from the core-mantle boundary.[41] Supporters of this hypothesis hold that any of these events could lead to a large scale disruption of the dynamo, effectively turning off the geomagnetic field. Because the magnetic field is stable in either the present north–south orientation or a reversed orientation, they propose that when the field recovers from such a disruption it spontaneously chooses one state or the other, such that half the recoveries become reversals. This proposed mechanism does not appear to work in a quantitative model, and the evidence from stratigraphy for a correlation between reversals and impact events is weak. There is no evidence for a reversal connected with the impact event that caused the Cretaceous–Paleogene extinction event.[42]

Effects on biosphere edit

Shortly after the first geomagnetic polarity time scales were produced, scientists began exploring the possibility that reversals could be linked to extinction events.[17] Many such arguments were based on an apparent periodicity in the rate of reversals, but more careful analyses show that the reversal record is not periodic.[18] It may be that the ends of superchrons have caused vigorous convection leading to widespread volcanism, and that the subsequent airborne ash caused extinctions.[43] Tests of correlations between extinctions and reversals are difficult for several reasons. Larger animals are too scarce in the fossil record for good statistics, so paleontologists have analyzed microfossil extinctions. Even microfossil data can be unreliable if there are hiatuses in the fossil record. It can appear that the extinction occurs at the end of a polarity interval when the rest of that polarity interval was simply eroded away.[26] Statistical analysis shows no evidence for a correlation between reversals and extinctions.[44][45]

Most proposals tying reversals to extinction events assume that the Earth's magnetic field would be much weaker during reversals. Possibly the first such hypothesis was that high-energy particles trapped in the Van Allen radiation belt could be liberated and bombard the Earth.[45][46] Detailed calculations confirm that if the Earth's dipole field disappeared entirely (leaving the quadrupole and higher components), most of the atmosphere would become accessible to high-energy particles but would act as a barrier to them, and cosmic ray collisions would produce secondary radiation of beryllium-10 or chlorine-36. A 2012 German study of Greenland ice cores showed a peak of beryllium-10 during a brief complete reversal 41,000 years ago, which led to the magnetic field strength dropping to an estimated 5% of normal during the reversal.[47] There is evidence that this occurs both during secular variation[48][49] and during reversals.[50][51]

A hypothesis by McCormac and Evans assumes that the Earth's field disappears entirely during reversals.[52] They argue that the atmosphere of Mars may have been eroded away by the solar wind because it had no magnetic field to protect it. They predict that ions would be stripped away from Earth's atmosphere above 100 km. Paleointensity measurements show that the magnetic field has not disappeared during reversals. Based on paleointensity data for the last 800,000 years,[53] the magnetopause is still estimated to have been at about three Earth radii during the Brunhes–Matuyama reversal.[45] Even if the internal magnetic field did disappear, the solar wind can induce a magnetic field in the Earth's ionosphere sufficient to shield the surface from energetic particles.[54]

See also edit

References edit

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  53. ^ Guyodo, Yohan; Valet, Jean-Pierre (20 May 1999). "Global changes in intensity of the Earth's magnetic field during the past 800 kyr" (PDF). Nature. 399 (6733): 249–252. Bibcode:1999Natur.399..249G. doi:10.1038/20420. hdl:1874/1501. S2CID 4426319.
  54. ^ Birk, G. T.; Lesch, H.; Konz, C. (2004). "Solar wind induced magnetic field around the unmagnetized Earth". Astronomy & Astrophysics. 420 (2): L15–L18. arXiv:astro-ph/0404580. Bibcode:2004A&A...420L..15B. doi:10.1051/0004-6361:20040154. S2CID 15352610.

Further reading edit

  • Barry, Patrick (11 May 2006). "Ships' logs give clues to Earth's magnetic decline". New Scientist. Retrieved 8 January 2019.
  • Hoffman, Kenneth A. (18 July 1995). . EOS. 76: 289. doi:10.1029/95EO00172. Archived from the original on 16 March 2009.
  • Jacobs, J. A. (1994). Reversals of the Earth's magnetic field (2nd ed.). Cambridge University Press. ISBN 978-0521450720.
  • Ogg, J. G. (2012). "Geomagnetic polarity time scale". In Gradstein, F. M.; Ogg, J. G.; Schmitz, Mark; Ogg, Gabi (eds.). The geologic time scale 2012. Volume 2 (1st ed.). Elsevier. pp. 85–114. ISBN 978-0444594259.
  • Okada, Makoto; Niitsuma, Nobuaki (July 1989). "Detailed paleomagnetic records during the Brunhes-Matuyama geomagnetic reversal, and a direct determination of depth lag for magnetization in marine sediments". Physics of the Earth and Planetary Interiors. 56 (1–2): 133–150. Bibcode:1989PEPI...56..133O. doi:10.1016/0031-9201(89)90043-5.
  • Opdyke, Neil D. (1996). Magnetic stratigraphy. Academic Press. ISBN 978-0080535722.
  • "Look down, look up, look out!". The Economist. 10 May 2007. Retrieved 8 January 2019.
  • Turner, Gillian (2011). North Pole, South Pole: The epic quest to solve the great mystery of Earth's magnetism. New York, NY: The Experiment. ISBN 9781615190317.

External links edit

 
The Wikibook Historical Geology has a page on the topic of: Geomagnetic reversals
  • Is it true that the Earth's magnetic field is about to flip? physics.org, accessed 8 January 2019
  • Pole Reversal Happens All The (Geologic) Time NASA, accessed 1 March 2022

January 01, 1970
geomagnetic, reversal, magnetic, reversal, redirects, here, switching, magnet, magnetization, reversal, polarity, reversal, redirects, here, seismic, anomaly, polarity, reversal, seismology, geomagnetic, reversal, change, planet, magnetic, field, such, that, p. Magnetic reversal redirects here For switching of a magnet see Magnetization reversal Polarity reversal redirects here For a seismic anomaly see Polarity reversal seismology A geomagnetic reversal is a change in a planet s magnetic field such that the positions of magnetic north and magnetic south are interchanged not to be confused with geographic north and geographic south The Earth s field has alternated between periods of normal polarity in which the predominant direction of the field was the same as the present direction and reverse polarity in which it was the opposite These periods are called chrons Geomagnetic polarity during the last 5 million years Pliocene and Quaternary late Cenozoic Era Dark areas denote periods where the polarity matches today s normal polarity light areas denote periods where that polarity is reversed Reversal occurrences are statistically random There have been at least 183 reversals over the last 83 million years on average once every 450 000 years The latest the Brunhes Matuyama reversal occurred 780 000 years ago 1 with widely varying estimates of how quickly it happened Other sources estimate that the time that it takes for a reversal to complete is on average around 7 000 years for the four most recent reversals 2 Clement 2004 suggests that this duration is dependent on latitude with shorter durations at low latitudes and longer durations at mid and high latitudes 2 Although variable the duration of a full reversal is typically between 2 000 and 12 000 years 3 Although there have been periods in which the field reversed globally such as the Laschamp excursion for several hundred years 4 these events are classified as excursions rather than full geomagnetic reversals Stable polarity chrons often show large rapid directional excursions which occur more often than reversals and could be seen as failed reversals During such an excursion the field reverses in the liquid outer core but not in the solid inner core Diffusion in the outer core is on timescales of 500 years or less while that of the inner core is longer around 3 000 years 5 Contents 1 History 2 Observing past fields 3 Geomagnetic polarity time scale 3 1 Changing frequency over time 3 2 Superchrons 3 3 Statistical properties 4 Character of transitions 4 1 Duration 5 Causes 6 Effects on biosphere 7 See also 8 References 9 Further reading 10 External linksHistory editIn the early 20th century geologists such as Bernard Brunhes first noticed that some volcanic rocks were magnetized opposite to the direction of the local Earth s field The first systematic evidence for and time scale estimate of the magnetic reversals were made by Motonori Matuyama in the late 1920s he observed that rocks with reversed fields were all of early Pleistocene age or older At the time the Earth s polarity was poorly understood and the possibility of reversal aroused little interest 6 7 Three decades later when Earth s magnetic field was better understood theories were advanced suggesting that the Earth s field might have reversed in the remote past Most paleomagnetic research in the late 1950s included an examination of the wandering of the poles and continental drift Although it was discovered that some rocks would reverse their magnetic field while cooling it became apparent that most magnetized volcanic rocks preserved traces of the Earth s magnetic field at the time the rocks had cooled In the absence of reliable methods for obtaining absolute ages for rocks it was thought that reversals occurred approximately every million years 6 7 The next major advance in understanding reversals came when techniques for radiometric dating were improved in the 1950s Allan Cox and Richard Doell at the United States Geological Survey wanted to know whether reversals occurred at regular intervals and they invited geochronologist Brent Dalrymple to join their group They produced the first magnetic polarity time scale in 1959 As they accumulated data they continued to refine this scale in competition with Don Tarling and Ian McDougall at the Australian National University A group led by Neil Opdyke at the Lamont Doherty Earth Observatory showed that the same pattern of reversals was recorded in sediments from deep sea cores 7 During the 1950s and 1960s information about variations in the Earth s magnetic field was gathered largely by means of research vessels but the complex routes of ocean cruises rendered the association of navigational data with magnetometer readings difficult Only when data were plotted on a map did it become apparent that remarkably regular and continuous magnetic stripes appeared on the ocean floors 6 7 nbsp In 1963 Frederick Vine and Drummond Matthews provided a simple explanation by combining the seafloor spreading theory of Harry Hess with the known time scale of reversals sea floor rock is magnetized in the direction of the field when it is formed Thus sea floor spreading from a central ridge will produce pairs of magnetic stripes parallel to the ridge 8 Canadian L W Morley independently proposed a similar explanation in January 1963 but his work was rejected by the scientific journals Nature and Journal of Geophysical Research and remained unpublished until 1967 when it appeared in the literary magazine Saturday Review 6 The Morley Vine Matthews hypothesis was the first key scientific test of the seafloor spreading theory of continental drift 7 Past field reversals are recorded in the solidified ferrimagnetic minerals of consolidated sedimentary deposits or cooled volcanic flows on land Beginning in 1966 Lamont Doherty Geological Observatory scientists found that the magnetic profiles across the Pacific Antarctic Ridge were symmetrical and matched the pattern in the north Atlantic s Reykjanes ridge The same magnetic anomalies were found over most of the world s oceans which permitted estimates for when most of the oceanic crust had developed 6 7 Observing past fields edit nbsp Geomagnetic polarity since the middle Jurassic Dark areas denote periods where the polarity matches today s polarity while light areas denote periods where that polarity is reversed The Cretaceous Normal superchron is visible as the broad uninterrupted black band near the middle of the image Because no existing unsubducted sea floor or sea floor thrust onto continental plates is more than about 180 million years Ma old other methods are necessary for detecting older reversals Most sedimentary rocks incorporate minute amounts of iron rich minerals whose orientation is influenced by the ambient magnetic field at the time at which they formed These rocks can preserve a record of the field if it is not later erased by chemical physical or biological change Because Earth s magnetic field is a global phenomenon similar patterns of magnetic variations at different sites may be used to help calculate age in different locations The past four decades of paleomagnetic data about seafloor ages up to 250 Ma has been useful in estimating the age of geologic sections elsewhere While not an independent dating method it depends on absolute age dating methods like radioisotopic systems to derive numeric ages It has become especially useful when studying metamorphic and igneous rock formations where index fossils are seldom available Geomagnetic polarity time scale editFurther information Magnetostratigraphy Through analysis of seafloor magnetic anomalies and dating of reversal sequences on land paleomagnetists have been developing a Geomagnetic Polarity Time Scale The current time scale contains 184 polarity intervals in the last 83 million years and therefore 183 reversals 9 10 Changing frequency over time edit The rate of reversals in the Earth s magnetic field has varied widely over time Around 72 Ma the field reversed 5 times in a million years In a 4 million year period centered on 54 Ma there were 10 reversals at around 42 Ma 17 reversals took place in the span of 3 million years In a period of 3 million years centering on 24 Ma 13 reversals occurred No fewer than 51 reversals occurred in a 12 million year period centering on 15 Ma Two reversals occurred during a span of 50 000 years These eras of frequent reversals have been counterbalanced by a few superchrons long periods when no reversals took place 11 Superchrons edit A superchron is a polarity interval lasting at least 10 million years There are two well established superchrons the Cretaceous Normal and the Kiaman A third candidate the Moyero is more controversial The Jurassic Quiet Zone in ocean magnetic anomalies was once thought to represent a superchron but is now attributed to other causes The Cretaceous Normal also called the Cretaceous Superchron or C34 lasted for almost 40 million years from about 120 to 83 million years ago including stages of the Cretaceous period from the Aptian through the Santonian The frequency of magnetic reversals steadily decreased prior to the period reaching its low point no reversals during the period Between the Cretaceous Normal and the present the frequency has generally increased slowly 12 The Kiaman Reverse Superchron lasted from approximately the late Carboniferous to the late Permian or for more than 50 million years from around 312 to 262 million years ago 12 The magnetic field had reversed polarity The name Kiaman derives from the Australian town of Kiama where some of the first geological evidence of the superchron was found in 1925 13 The Ordovician is suspected to have hosted another superchron called the Moyero Reverse Superchron lasting more than 20 million years 485 to 463 million years ago Thus far this possible superchron has only been found in the Moyero river section north of the polar circle in Siberia 14 Moreover the best data from elsewhere in the world do not show evidence for this superchron 15 Certain regions of ocean floor older than 160 Ma have low amplitude magnetic anomalies that are hard to interpret They are found off the east coast of North America the northwest coast of Africa and the western Pacific They were once thought to represent a superchron called the Jurassic Quiet Zone but magnetic anomalies are found on land during this period The geomagnetic field is known to have low intensity between about 130 Ma and 170 Ma and these sections of ocean floor are especially deep causing the geomagnetic signal to be attenuated between the seabed and the surface 15 Statistical properties edit Several studies have analyzed the statistical properties of reversals in the hope of learning something about their underlying mechanism The discriminating power of statistical tests is limited by the small number of polarity intervals Nevertheless some general features are well established In particular the pattern of reversals is random There is no correlation between the lengths of polarity intervals 16 There is no preference for either normal or reversed polarity and no statistical difference between the distributions of these polarities This lack of bias is also a robust prediction of dynamo theory 12 There is no rate of reversals as they are statistically random The randomness of the reversals is inconsistent with periodicity but several authors have claimed to find periodicity 17 However these results are probably artifacts of an analysis using sliding windows to attempt to determine reversal rates 18 Most statistical models of reversals have analyzed them in terms of a Poisson process or other kinds of renewal process A Poisson process would have on average a constant reversal rate so it is common to use a non stationary Poisson process However compared to a Poisson process there is a reduced probability of reversal for tens of thousands of years after a reversal This could be due to an inhibition in the underlying mechanism or it could just mean that some shorter polarity intervals have been missed 12 A random reversal pattern with inhibition can be represented by a gamma process In 2006 a team of physicists at the University of Calabria found that the reversals also conform to a Levy distribution which describes stochastic processes with long ranging correlations between events in time 19 20 The data are also consistent with a deterministic but chaotic process 21 Character of transitions editDuration edit Most estimates for the duration of a polarity transition are between 1 000 and 10 000 years 12 but some estimates are as quick as a human lifetime 22 During a transition the magnetic field will not vanish completely but many poles might form chaotically in different places during reversal until it stabilizes again 23 24 Studies of 16 7 million year old lava flows on Steens Mountain Oregon indicate that the Earth s magnetic field is capable of shifting at a rate of up to 6 degrees per day 25 This was initially met with skepticism from paleomagnetists Even if changes occur that quickly in the core the mantle which is a semiconductor is thought to remove variations with periods less than a few months A variety of possible rock magnetic mechanisms were proposed that would lead to a false signal 26 That said paleomagnetic studies of other sections from the same region the Oregon Plateau flood basalts give consistent results 27 28 It appears that the reversed to normal polarity transition that marks the end of Chron C5Cr 16 7 million years ago contains a series of reversals and excursions 29 In addition geologists Scott Bogue of Occidental College and Jonathan Glen of the US Geological Survey sampling lava flows in Battle Mountain Nevada found evidence for a brief several year long interval during a reversal when the field direction changed by over 50 degrees The reversal was dated to approximately 15 million years ago 30 31 In 2018 researchers reported a reversal lasting only 200 years 32 A 2019 paper estimates that the most recent reversal 780 000 years ago lasted 22 000 years 33 34 Causes edit nbsp NASA computer simulation using the model of Glatzmaier and Roberts 35 The tubes represent magnetic field lines blue when the field points towards the center and yellow when away The rotation axis of the Earth is centered and vertical The dense clusters of lines are within the Earth s core 24 The magnetic field of the Earth and of other planets that have magnetic fields is generated by dynamo action in which convection of molten iron in the planetary core generates electric currents which in turn give rise to magnetic fields 12 In simulations of planetary dynamos reversals often emerge spontaneously from the underlying dynamics For example Gary Glatzmaier and collaborator Paul Roberts of UCLA ran a numerical model of the coupling between electromagnetism and fluid dynamics in the Earth s interior Their simulation reproduced key features of the magnetic field over more than 40 000 years of simulated time and the computer generated field reversed itself 35 36 Global field reversals at irregular intervals have also been observed in the laboratory liquid metal experiment VKS2 37 In some simulations this leads to an instability in which the magnetic field spontaneously flips over into the opposite orientation This scenario is supported by observations of the solar magnetic field which undergoes spontaneous reversals every 9 12 years With the Sun it is observed that the solar magnetic intensity greatly increases during a reversal whereas reversals on Earth seem to occur during periods of low field strength 38 Some scientists such as Richard A Muller think that geomagnetic reversals are not spontaneous processes but rather are triggered by external events that directly disrupt the flow in the Earth s core Proposals include impact events 39 40 or internal events such as the arrival of continental slabs carried down into the mantle by the action of plate tectonics at subduction zones or the initiation of new mantle plumes from the core mantle boundary 41 Supporters of this hypothesis hold that any of these events could lead to a large scale disruption of the dynamo effectively turning off the geomagnetic field Because the magnetic field is stable in either the present north south orientation or a reversed orientation they propose that when the field recovers from such a disruption it spontaneously chooses one state or the other such that half the recoveries become reversals This proposed mechanism does not appear to work in a quantitative model and the evidence from stratigraphy for a correlation between reversals and impact events is weak There is no evidence for a reversal connected with the impact event that caused the Cretaceous Paleogene extinction event 42 Effects on biosphere editShortly after the first geomagnetic polarity time scales were produced scientists began exploring the possibility that reversals could be linked to extinction events 17 Many such arguments were based on an apparent periodicity in the rate of reversals but more careful analyses show that the reversal record is not periodic 18 It may be that the ends of superchrons have caused vigorous convection leading to widespread volcanism and that the subsequent airborne ash caused extinctions 43 Tests of correlations between extinctions and reversals are difficult for several reasons Larger animals are too scarce in the fossil record for good statistics so paleontologists have analyzed microfossil extinctions Even microfossil data can be unreliable if there are hiatuses in the fossil record It can appear that the extinction occurs at the end of a polarity interval when the rest of that polarity interval was simply eroded away 26 Statistical analysis shows no evidence for a correlation between reversals and extinctions 44 45 Most proposals tying reversals to extinction events assume that the Earth s magnetic field would be much weaker during reversals Possibly the first such hypothesis was that high energy particles trapped in the Van Allen radiation belt could be liberated and bombard the Earth 45 46 Detailed calculations confirm that if the Earth s dipole field disappeared entirely leaving the quadrupole and higher components most of the atmosphere would become accessible to high energy particles but would act as a barrier to them and cosmic ray collisions would produce secondary radiation of beryllium 10 or chlorine 36 A 2012 German study of Greenland ice cores showed a peak of beryllium 10 during a brief complete reversal 41 000 years ago which led to the magnetic field strength dropping to an estimated 5 of normal during the reversal 47 There is evidence that this occurs both during secular variation 48 49 and during reversals 50 51 A hypothesis by McCormac and Evans assumes that the Earth s field disappears entirely during reversals 52 They argue that the atmosphere of Mars may have been eroded away by the solar wind because it had no magnetic field to protect it They predict that ions would be stripped away from Earth s atmosphere above 100 km Paleointensity measurements show that the magnetic field has not disappeared during reversals Based on paleointensity data for the last 800 000 years 53 the magnetopause is still estimated to have been at about three Earth radii during the Brunhes Matuyama reversal 45 Even if the internal magnetic field did disappear the solar wind can induce a magnetic field in the Earth s ionosphere sufficient to shield the surface from energetic particles 54 See also editList of geomagnetic reversals including ages Magnetic anomalyReferences edit Johnson Scott K 11 August 2019 The last magnetic pole flip saw 22 000 years of weirdness When the Earth s magnetic poles trade places they take a while to get sorted Ars Technica Retrieved 11 August 2019 a b Clement Bradford M 2004 Dependence of the duration of geomagnetic polarity reversals on site latitude Nature 428 6983 637 640 Bibcode 2004Natur 428 637C doi 10 1038 nature02459 ISSN 0028 0836 PMID 15071591 S2CID 4356044 Glatzmaier G A Coe R S 2015 Magnetic Polarity Reversals in the Core Treatise on Geophysics Elsevier pp 279 295 doi 10 1016 b978 0 444 53802 4 00146 9 ISBN 978 0444538031 Nowaczyk N R Arz H W Frank U Kind J Plessen B 2012 Dynamics of the Laschamp geomagnetic excursion from Black Sea sediments Earth and Planetary Science Letters 351 352 54 69 Bibcode 2012E amp PSL 351 54N doi 10 1016 j epsl 2012 06 050 Gubbins David 1999 The distinction between geomagnetic excursions and reversals Geophysical Journal International 137 1 F1 F4 doi 10 1046 j 1365 246x 1999 00810 x a b c d e Cox Allan 1973 Plate tectonics and geomagnetic reversal San Francisco California W H Freeman pp 138 145 222 228 ISBN 0 7167 0258 4 a b c d e f Glen William 1982 The Road to Jaramillo Critical Years of the Revolution in Earth Science Stanford University Press ISBN 0 8047 1119 4 Vine Frederick J Drummond H Matthews 1963 Magnetic Anomalies over Oceanic Ridges Nature 199 4897 947 949 Bibcode 1963Natur 199 947V doi 10 1038 199947a0 S2CID 4296143 Cande S C Kent D V 1995 Revised calibration of 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4247637 a b Merrill Ronald T 2010 Our magnetic Earth the science of geomagnetism Chicago The University of Chicago Press ISBN 978 0 226 52050 6 Prevot M Mankinen E Coe R Gromme C 1985 The Steens Mountain Oregon Geomagnetic Polarity Transition 2 Field Intensity Variations and Discussion of Reversal Models J Geophys Res 90 B12 10417 10448 Bibcode 1985JGR 9010417P doi 10 1029 JB090iB12p10417 Mankinen Edward A Prevot Michel Gromme C Sherman Coe Robert S 1 January 1985 The Steens Mountain Oregon Geomagnetic Polarity Transition 1 Directional History Duration of Episodes and Rock Magnetism Journal of Geophysical Research 90 B12 10393 Bibcode 1985JGR 9010393M doi 10 1029 JB090iB12p10393 Jarboe Nicholas A Coe Robert S Glen Jonathan M G 2011 Evidence from lava flows for complex polarity transitions the new composite Steens Mountain reversal record Geophysical Journal International 186 2 580 602 Bibcode 2011GeoJI 186 580J doi 10 1111 j 1365 246X 2011 05086 x Witze Alexandra September 2 2010 Earth s Magnetic Field Flipped Superfast Wired Bogue S W 10 November 2010 Very rapid geomagnetic field change recorded by the partial remagnetization of a lava flow Geophys Res Lett 37 21 L21308 Bibcode 2010GeoRL 3721308B doi 10 1029 2010GL044286 S2CID 129896450 Byrd Deborah 21 August 2018 Researchers find fast flip in Earth s magnetic field EarthSky Retrieved 22 August 2018 Singer Brad S Jicha Brian R Mochizuki Nobutatsu Coe Robert S August 7 2019 Synchronizing volcanic sedimentary and ice core records of Earth s last magnetic polarity reversal Science Advances 5 8 eaaw4621 Bibcode 2019SciA 5 4621S doi 10 1126 sciadv aaw4621 ISSN 2375 2548 PMC 6685714 PMID 31457087 Science Passant Rabie August 7 2019 Earth s Last Magnetic Pole Flip Took Much Longer Than We Thought Space com Retrieved August 8 2019 a b Glatzmaier Gary A Roberts Paul H A three dimensional self consistent computer simulation of a geomagnetic field reversal Nature Vol 377 pp 203 209 Bibcode 1995Natur 377 203G doi 10 1038 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9478888 Raisbeck G M Yiou F Bourles D Kent D V 23 May 1985 Evidence for an increase in cosmogenic 10Be during a geomagnetic reversal Nature 315 6017 315 317 Bibcode 1985Natur 315 315R doi 10 1038 315315a0 S2CID 4324833 Raisbeck G M Yiou F Cattani O Jouzel J 2 November 2006 10Be evidence for the Matuyama Brunhes geomagnetic reversal in the EPICA Dome C ice core Nature 444 7115 82 84 Bibcode 2006Natur 444 82R doi 10 1038 nature05266 PMID 17080088 S2CID 4425406 McCormac Billy M Evans John E 20 September 1969 Consequences of Very Small Planetary Magnetic Moments Nature 223 5212 1255 Bibcode 1969Natur 223 1255M doi 10 1038 2231255a0 S2CID 4295498 Guyodo Yohan Valet Jean Pierre 20 May 1999 Global changes in intensity of the Earth s magnetic field during the past 800 kyr PDF Nature 399 6733 249 252 Bibcode 1999Natur 399 249G doi 10 1038 20420 hdl 1874 1501 S2CID 4426319 Birk G T Lesch H Konz C 2004 Solar wind induced magnetic field around the unmagnetized Earth Astronomy amp Astrophysics 420 2 L15 L18 arXiv astro ph 0404580 Bibcode 2004A amp A 420L 15B doi 10 1051 0004 6361 20040154 S2CID 15352610 Further reading editBarry Patrick 11 May 2006 Ships logs give clues to Earth s magnetic decline New Scientist Retrieved 8 January 2019 Hoffman Kenneth A 18 July 1995 How Are Geomagnetic Reversals Related to Field Intensity EOS 76 289 doi 10 1029 95EO00172 Archived from the original on 16 March 2009 Jacobs J A 1994 Reversals of the Earth s magnetic field 2nd ed Cambridge University Press ISBN 978 0521450720 Ogg J G 2012 Geomagnetic polarity time scale In Gradstein F M Ogg J G Schmitz Mark Ogg Gabi eds The geologic time scale 2012 Volume 2 1st ed Elsevier pp 85 114 ISBN 978 0444594259 Okada Makoto Niitsuma Nobuaki July 1989 Detailed paleomagnetic records during the Brunhes Matuyama geomagnetic reversal and a direct determination of depth lag for magnetization in marine sediments Physics of the Earth and Planetary Interiors 56 1 2 133 150 Bibcode 1989PEPI 56 133O doi 10 1016 0031 9201 89 90043 5 Opdyke Neil D 1996 Magnetic stratigraphy Academic Press ISBN 978 0080535722 Look down look up look out The Economist 10 May 2007 Retrieved 8 January 2019 Turner Gillian 2011 North Pole South Pole The epic quest to solve the great mystery of Earth s magnetism New York NY The Experiment ISBN 9781615190317 External links edit nbsp The Wikibook Historical Geology has a page on the topic of Geomagnetic reversals Is it true that the Earth s magnetic field is about to flip physics org accessed 8 January 2019 Pole Reversal Happens All The Geologic Time NASA accessed 1 March 2022 Retrieved from https en wikipedia org w index php title Geomagnetic reversal amp oldid 1216905966, wikipedia, wiki, book, books, library,

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