Long-term variations in palaeointensity

Selkin, P.A.; Tauxe, Lisa

doi:10.1098/rsta.2000.0574

Cited by 343 publications

(341 citation statements)

References 37 publications

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“…This points to the necessity of using experimental designs that avoid or correct for pervasive MD behaviors with sufficient independent cooling units to obtain reliable time-averaged paleointensities. The consistency of our high-fidelity MD-corrected Galapagos lava paleointensity results and the reported SD-behaved McMurdo (and now also Iceland) results with GAD predictions allows us to confirm with more confidence that the Pliocene-Pleistocene average paleointensity is indeed much weaker than today's geomagnetic field, as already suspected from results from targeted SD recorders like submarine basaltic glass (19). This has several significant implications.…”

Section: Significancesupporting

confidence: 72%

“…Foremost, these results show that the past several-millionyear-long time-averaged geomagnetic field is predominantly that of a GAD in direction as well as intensity, validating, for example, the calculation of VADMs and various total field models [e.g., TK03 (20)]. Second, our average dipolar paleointensity estimation for the past ∼5 My is consistent with average paleointensities estimated for the most SD material for the past 140 My [VADM = ∼4.2 × 10 22 A·m 2 (21)] and even the past 300 My [VADM = ∼4.6 × 10 22 A·m 2 (19)], values that are also only about 50-60% of the present-day magnitude. Third, a lower average paleointensity over at least the past few million years results in a shorter average steady-state magnetopause standoff distance of only ∼9 Earth radii (R E ) compared with ∼11 R E today (22).…”

Section: Significancesupporting

confidence: 63%

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Weaker axially dipolar time-averaged paleomagnetic field based on multidomain-corrected paleointensities from Galapagos lavas

Wang

Kent

Rochette

2015

Proc. Natl. Acad. Sci. U.S.A.

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The geomagnetic field is predominantly dipolar today, and highfidelity paleomagnetic mean directions from all over the globe strongly support the geocentric axial dipole (GAD) hypothesis for the past few million years. However, the bulk of paleointensity data fails to coincide with the axial dipole prediction of a factor-of-2 equator-to-pole increase in mean field strength, leaving the core dynamo process an enigma. Here, we obtain a multidomain-corrected Pliocene-Pleistocene average paleointensity of 21.6 ± 11.0 μT recorded by 27 lava flows from the Galapagos Archipelago near the Equator. Our new result in conjunction with a published comprehensive study of single-domain-behaved paleointensities from Antarctica (33.4 ± 13.9 μT) that also correspond to GAD directions suggests that the overall average paleomagnetic field over the past few million years has indeed been dominantly dipolar in intensity yet only ∼60% of the present-day field strength, with a long-term average virtual axial dipole magnetic moment of the Earth of only 4.9 ± 2.4 × 10 22 A·m 2 .geomagnetism | paleomagnetism | Thellier paleointensity experiment | multidomain correction | time-averaged dipole field I n 1600, William Gilbert (1) articulated that Earth's magnetic field was well approximated by a bar magnet centered along its rotation axis. This model has become elaborated for the timeaveraged field as the geocentric axial dipole (GAD) hypothesis, which essentially all paleogeographic reconstructions rely on. Paleomagnetic field directions for the past 5 My for both normal and reverse polarity chrons from around the globe show that the mean inclinations closely correspond to the GAD model (2), which predicts a simple relationship between mean inclination, I, and site latitude, Lat: tan(I) = 2 × tan(Lat). The GAD hypothesis also predicts that the mean field intensity should vary with latitude, as [1 + 3 × cos 2 (90°− Lat)] 1/2 , whereby the intensity at the poles is twice that at the Equator. The modern field [i.e., International Geomagnetic Reference Field (IGRF) (3)] is dominated by an axial dipole with steep field directions at the poles about twice the intensity (∼60 μT) compared with that (∼30 μT) of near-horizontal directions in the equatorial belt and corresponds to a virtual axial dipole moment (VADM) of ∼8 × 10 22 A·m 2 . However, the expected latitudinal dependence has yet to be shown in the current global paleointensity database PINT2014.01 (4) even for the most recent past 5 My. Analyses of these data using various selection criteria tend to show a puzzling near uniformity of mean intensities with latitude and largely because of the dominance of data from 15°t o 30°latitude with ages of 0.03-0.5 Ma, which average close to the present field intensity, would suggest the time-averaged field for normal and reversed polarity chrons over the past 5 My was also near the present VADM of ∼8 × 10 22 A·m 2 ( Fig. 1 and SI Appendix, SI Text and Fig. S1).The factor-of-2 difference between the poles and Equator provides the maximum signal to res...

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Section: Significancesupporting

confidence: 72%

Section: Significancesupporting

confidence: 63%

Weaker axially dipolar time-averaged paleomagnetic field based on multidomain-corrected paleointensities from Galapagos lavas

Wang

Kent

Rochette

2015

Proc. Natl. Acad. Sci. U.S.A.

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“…SCAT is meant to replace the various statistics designed to test for sample alteration, pTRM tails and excessive noise in the NRM lost versus pTRM gained (Arai plots of Nagata et al [1963]). The slope of the best-fit line through the data in the Arai plot is allowed to vary within the bounds defined by threshold value of the ''scatter'' statistic [Coe et al, 1978, renamed by Selkin andTauxe, 2000] which is the ratio of the standard error of the slope b to the absolute value of the slope (jbj). The threshold value of , threshold , can be used to define two bounding lines (Figure 2).…”

Section: Selection Criteriamentioning

confidence: 99%

“…In an attempt to compare data of similar quality, Selkin and Tauxe [2000] had excluded all data sets that were not done by double heating methods including pTRM checks (a widely used test for alteration). In fact, the exclusion of studies with no pTRM checks does indeed change the debate concerning the Jurassic field as none of the Armenian data had been subjected to the complete paleointensity experiment including pTRM checks.…”

Section: The Long-term Average Intensitymentioning

confidence: 99%

Paleointensity results from the Jurassic: New constraints from submarine basaltic glasses of ODP Site 801C

Tauxe

Gee

Steiner

et al. 2013

Geochem. Geophys. Geosyst.

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“…To date no long term correlation has been found between average absolute intensity of the paleomagnetic field and long term reversal rate (Selkin and Tauxe, 2000), although one was suspected for some time (see Prévot et al, 1990). It should be emphasized, however, that there remain insufficient data to characterize absolute paleointensity very well over the past 300 Ma, and in the CNS a period which is of great interest because of the absence of documented reversals there is only a handful of reliable absolute paleointensity data available despite continuing efforts to acquire such observations (see e.g.…”

Section: :2 Reversal Rates and Other Properties Of The Geomagnetic Fmentioning

confidence: 99%

The Fluid Mechanics of Astrophysics and Geophysics

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Paleomagnetic data on geomagnetic reversals are divided into two general categories: times of occurrence, and records of directional and/or intensity changes for transitions at individual locations. Despite considerable efforts expended in acquiring paleomagnetic reversal records, a detailed picture of the reversal process is still lacking, along with any means of clearly identifying when the magnetic field has entered a transitional state destined to lead to a reversal. Accurate dating remains critical to making inferences about timing and structure of reversals and excursions. Controversy remains about the significance of such features as the preferred longitudinal paths that virtual geomagnetic poles at some sites seem to follow during excursions and reversals. Reversal rates are estimated under the assumption that reversal occurrence times can be described as a Poisson process. Correlations are sought between reversal rates and other properties of the paleomagnetic secular variation, and more general models for reversals and secular variations are being developed to provide predictions of the power spectrum of geomagnetic intensity variations for comparison with those derived from long paleomagnetic records. These analyses may ultimately allow the identification of any characteristic time scales associated with the geomagnetic reversal process, and should prove useful in evaluating the behavior observed from numerical simulations of the geodynamo.

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Long-term variations in palaeointensity

Cited by 343 publications

References 37 publications

Weaker axially dipolar time-averaged paleomagnetic field based on multidomain-corrected paleointensities from Galapagos lavas

Weaker axially dipolar time-averaged paleomagnetic field based on multidomain-corrected paleointensities from Galapagos lavas

Paleointensity results from the Jurassic: New constraints from submarine basaltic glasses of ODP Site 801C

The Fluid Mechanics of Astrophysics and Geophysics

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