Solar Cycle Variability Induced by Tilt Angle Scatter in a Babcock–Leighton Solar Dynamo Model

Karak, Bidya Binay; Miesch, Mark S.

doi:10.3847/1538-4357/aa8636

Cited by 87 publications

(106 citation statements)

References 84 publications

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“…In contrast to the results of Karak and Miesch (2017) we found strong correlation between the hemispheric asymmetry of the polar cap flux of cycle i and the asymmetry of hemispheric activity levels during the subsequent cycle i + 1. The time lag between the hemispheric lag in the onset of cycle i + 1 is also strongly correlated to the asymmetry of the polar cap flux of the preceding cycle.…”

Section: Resultscontrasting

confidence: 99%

“…According to their results, the intense inflow in one hemisphere leads to stronger toroidal fields and this asymmetry is sustained for more than one cycle. Karak and Miesch (2017), using their 3D surface flux transport and Babcock-Leighton solar dynamo model (Miesch and Dikpati 2014;Miesch and Teweldebirhan 2016), investigated the influence of the tilt angle distribution by adding random scatter on Joy's law and a tilt-angle saturation was also added to the model (on this point see also Lemerle and Charbonneau 2017).…”

Section: Introduction: Prediction Of Hemispheric Asymmetrymentioning

confidence: 99%

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Impact of rogue active regions on hemispheric asymmetry

Nagy

Lemerle

Charbonneau

2019

Advances in Space Research

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The solar dipole moment at activity minimum is a good predictor of the strength of the subsequent solar cycle. Through a systematic analysis using a state-of-the-art 2×2D solar dynamo model, we found that bipolar magnetic regions (BMR) with atypical characteristics can modify the strength of the next cycle via their impact on the buildup of the dipole moment as a sunspot cycle unfolds. In addition to summarizing these results, we present further effects of such "rogue" BMRs. These have the ability to generate hemispheric asymmetry in the subsequent sunspot cycle, since they modify the polar cap flux asymmetry of the ongoing cycle. We found strong correlation between the polar cap flux asymmetry of cycle i and the total pseudo sunspot number asymmetry of cycle i + 1. Good correlation also appears in the case of the time lag of the hemispheres of cycle i + 1.

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Section: Resultscontrasting

confidence: 99%

Section: Introduction: Prediction Of Hemispheric Asymmetrymentioning

confidence: 99%

Impact of rogue active regions on hemispheric asymmetry

Nagy

Lemerle

Charbonneau

2019

Advances in Space Research

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“…This scatter is essential to producing a varying solar cycle amplitude in Babcock-Leighton and surface flux transport models (e.g. Karak & Miesch 2017). We tested this theory by looking at the scatter of the separation between the polarities in high and low flux active regions.…”

Section: Scatter In the Motion Of The Magnetic Polaritiesmentioning

confidence: 99%

Average motion of emerging solar active region polarities

Schunker

Birch

Cameron

et al. 2019

A&A

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Aims. Our goal is to constrain models of active region formation by tracking the average motion of active region polarity pairs as they emerge onto the surface. Methods. We measured the motion of the two main opposite polarities in 153 emerging active regions (EARs) using line-of-sight magnetic field observations from the Solar Dynamics Observatory Helioseismic Emerging Active Region (SDO/HEAR) survey . We first measured the position of each of the polarities eight hours after emergence, when they could be clearly identified, using a feature recognition method. We then tracked their location forwards and backwards in time.Results. We find that, on average, the polarities emerge with an east-west orientation and in the first 0.1 days the separation speed between the polarities increases. At about 0.1 days after emergence, the average separation speed reaches a peak value of 229 ± 11 ms −1 , and then stars to decrease, and about 2.5 days after emergence the polarities stop separating. We also find that the separation and the separation speed in the east-west direction are systematically larger for active regions with higher flux. The scatter in the location of the polarities increases from about 5 Mm at the time of emergence to about 15 Mm at two days after emergence. Conclusions. Our results reveal two phases of the emergence process defined by the rate of change of the separation speed as the polarities move apart. Phase 1 begins when the opposite polarity pairs first appear at the surface, with an east-west alignment and an increasing separation speed. We define Phase 2 to begin when the separation speed starts to decrease, and ends when the polarities have stopped separating. This is consistent with the picture of Chen, Rempel, & Fan (2017): the peak of a flux tube breaks through the surface during Phase 1. During Phase 2 the magnetic field lines are straightened by magnetic tension, so that the polarities continue to move apart, until they eventually lie directly above their anchored subsurface footpoints. The scatter in the location of the polarities is consistent with the length and time scales of supergranulation, supporting the idea that convection buffets the polarities as they separate.

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“…By including detailed information about the individual tilt angles and magnetic polarities of the bipolar magnetic regions (BMRs) that emerged during cycle 23, the weak polar field around the end of cycle 23 is well reproduced by Jiang et al (2015). Recently series of BL dynamo models successfully reproduce the variability of the solar cycle by introducing random BMR tilts (Jiang et al 2013;Olemskoy & Kitchatinov 2013;Cameron & Schüssler 2017;Nagy et al 2017;Karak & Miesch 2017). The randomness of the sunspot emergence -part of the toroidal-to-poloidal part of the dynamo loop-makes the dynamo a stochastic process.…”

Section: Introductionmentioning

confidence: 99%

Predictability of the Solar Cycle Over One Cycle

Jiang

Wang

Jiao

et al. 2018

ApJ

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The prediction of the strength of future solar cycles is of interest because of its practical significance for space weather and as a test of our theoretical understanding of the solar cycle. The Babcock-Leighton mechanism allows predictions by assimilating the observed magnetic field on the surface. Since the emergence of sunspot groups has random properties, making it impossible to accurately predict the solar cycle and strongly limiting the scope of cycle predictions, we develop a scheme to investigate the predictability of the solar cycle over one cycle. When a cycle has been ongoing for more than three years, the sunspot group emergence can be predicted along with its uncertainty during the rest time of the cycle. The method for this prediction is to start by generating a set of random realizations that obey the statistical relations of the sunspot emergence. We then use a surface flux transport model to calculate the possible axial dipole moment evolutions. The correlation between the axial dipole moment at cycle minimum and the subsequent cycle strength and other empirical properties of solar cycles are used to predict the possible profiles of the subsequent cycle. We apply this scheme to predict the large-scale field evolution from 2018 to the end of cycle 25, whose maximum strength is expected to lie in the range from 93 to 155 with a probability of 95%.

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Solar Cycle Variability Induced by Tilt Angle Scatter in a Babcock–Leighton Solar Dynamo Model

Cited by 87 publications

References 84 publications

Impact of rogue active regions on hemispheric asymmetry

Impact of rogue active regions on hemispheric asymmetry

Average motion of emerging solar active region polarities

Predictability of the Solar Cycle Over One Cycle

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