Correction to: Compact and strong window core steering magnets with homogeneous dipole field

Twenty paired 14C and U/Th dates covering most of the past 50,000 yr have been obtained on a stalagmite from the Cango Caves in South Africa as well as some additional age-pairs on two stalagmites from Tasmania that partially fill a gap between 7 ka and 17 ka ago. After allowance is made for the initial apparent 14C ages, the age-pairs between 7 ka and 20 ka show satisfactory agreement with the coral data of Bard et al. (1990, 1993). The results for the Cango stalagmite between 25 ka and 50 ka show the 14C dates to be substantially younger than the U/Th dates except at 49 ka and 29 ka, where near correspondence occurs. The discrepancies may be explained by variations in 14C production caused by changes in the magnetic dipole field of the Earth. A tentative calibration curve for this period is offered.

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Can one use Earth’s magnetic axial dipole field intensity to predict reversals?

Geophysical Journal International ◽

10.1093/gji/ggaa542 ◽

2020 ◽

Author(s):

K Gwirtz ◽

M Morzfeld ◽

A Fournier ◽

G Hulot

Keyword(s):

Magnetic Field ◽

Numerical Models ◽

Dipole Field ◽

Axial Dipole ◽

Intensity Threshold ◽

Magnetic Dipole Field ◽

Model Hierarchy ◽

Definition Of ◽

Virtual Axial Dipole Moment ◽

Prediction Strategy

Summary We study predictions of reversals of Earth’s axial magnetic dipole field that are based solely on the dipole’s intensity. The prediction strategy is, roughly, that once the dipole intensity drops below a threshold, then the field will continue to decrease and a reversal (or a major excursion) will occur. We first present a rigorous definition of an intensity threshold-based prediction strategy and then describe a mathematical and numerical framework to investigate its validity and robustness in view of the data being limited. We apply threshold-based predictions to a hierarchy of numerical models, ranging from simple scalar models to 3D geodynamos. We find that the skill of threshold-based predictions varies across the model hierarchy. The differences in skill can be explained by differences in how reversals occur: if the field decreases towards a reversal slowly (in a sense made precise in this paper), the skill is high, and if the field decreases quickly, the skill is low. Such a property could be used as an additional criterion to identify which models qualify as Earth-like. Applying threshold-based predictions to Virtual Axial Dipole Moment (VADM) paleomagnetic reconstructions (PADM2M and Sint-2000) covering the last two million years, reveals a moderate skill of threshold-based predictions for Earth’s dynamo. Besides all of their limitations, threshold-based predictions suggests that no reversal is to be expected within the next 10 kyr. Most importantly, however, we show that considering an intensity threshold for identifying upcoming reversals is intrinsically limited by the dynamic behavior of Earth’s magnetic field.

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Magnetic field amplification in newly-born neutron stars

International Astronomical Union Colloquium ◽

10.1017/s0252921100042056 ◽

1996 ◽

Vol 160 ◽

pp. 435-436

Author(s):

H.-J. Wiebicke ◽

U. Geppert

Keyword(s):

Magnetic Field ◽

Neutron Stars ◽

Gravitational Collapse ◽

Dipole Field ◽

Numerical Calculations ◽

Selection Effects ◽

Thermoelectric Effects ◽

Field Amplification ◽

Seed Field ◽

Flux Conservation

AbstractWe present a scenario of magnetic field (MF) evolution of newly-born neutron stars (NSs). Numerical calculations show that in the hot phase of young NSs the MF can be amplified by thermoelectric effects, starting from a moderately strong seed-field. Therefore, there is no need to assume a 1012G dipole field immediately after the gravitational collapse of the supernova (SN) event. The widely accepted scenario for such a field to be produced by flux conservation during the collapse is critically discussed. Instead, it can be generated by amplification and selection effects in the first 104yrs, and by the subsequent fast ohmic decay of higher multipole components, when the NS cools down.

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One- and two-dimensional hybrid simulations of whistler mode waves in a dipole field

Journal of Geophysical Research Space Physics ◽

10.1002/2014ja020736 ◽

2015 ◽

Vol 120 (3) ◽

pp. 1908-1923 ◽

Cited By ~ 3

Author(s):

S. Wu ◽

R. E. Denton ◽

K. Liu ◽

M. K. Hudson

Keyword(s):

Dipole Field ◽

Two Dimensional ◽

Whistler Mode ◽

Whistler Mode Waves ◽

Hybrid Simulations

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Solvent density and long-range dipole field around a DNA-binding protein studied by molecular dynamics

Proteins Structure Function and Bioinformatics ◽

10.1002/(sici)1097-0134(20000801)40:2<193::aid-prot30>3.0.co;2-0 ◽

2000 ◽

Vol 40 (2) ◽

pp. 193-206 ◽

Cited By ~ 23

Author(s):

Junichi Higo ◽

Hidetoshi Kono ◽

Haruki Nakamura ◽

Akinori Sarai

Keyword(s):

Molecular Dynamics ◽

Dna Binding ◽

Long Range ◽

Binding Protein ◽

Dna Binding Protein ◽

Dipole Field ◽

Solvent Density

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Angular momentum loss and stellar spin-down in magnetic massive stars

Proceedings of the International Astronomical Union ◽

10.1017/s174392130903097x ◽

2008 ◽

Vol 4 (S259) ◽

pp. 423-424

Author(s):

Asif ud-Doula ◽

Stanley P. Owocki ◽

Richard H.D. Townsend

Keyword(s):

Angular Momentum ◽

Massive Stars ◽

Solid Angle ◽

Magnetic Confinement ◽

Dipole Field ◽

Hot Stars ◽

Momentum Loss ◽

Dipole Magnetic Field ◽

Angular Momentum Loss ◽

Compare And Contrast

AbstractWe examine the angular momentum loss and associated rotational spin-down for magnetic hot stars with a line-driven stellar wind and a rotation-aligned dipole magnetic field. Our analysis here is based on our previous 2-D numerical MHD simulation study that examines the interplay among wind, field, and rotation as a function of two dimensionless parameters, W(=Vrot/Vorb) and ‘wind magnetic confinement’, η∗ defined below. We compare and contrast the 2-D, time variable angular momentum loss of this dipole model of a hot-star wind with the classical 1-D steady-state analysis by Weber and Davis (WD), who used an idealized monopole field to model the angular momentum loss in the solar wind. Despite the differences, we find that the total angular momentum loss averaged over both solid angle and time follows closely the general WD scaling ~ ṀΩR2A. The key distinction is that for a dipole field Alfvèn radius RA is significantly smaller than for the monopole field WD used in their analyses. This leads to a slower stellar spin-down for the dipole field with typical spin-down times of order 1 Myr for several known magnetic massive stars.

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