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Towards an algebraic method of solar cycle prediction

K. Petrovay, Melinda Nagy, Anthony R. Yeates

2020Journal of Space Weather and Space Climate43 citationsDOIOpen Access PDF

Abstract

We discuss the potential use of an algebraic method to compute the value of the solar axial dipole moment at solar minimum, widely considered to be the most reliable precursor of the activity level in the next solar cycle. The method consists of summing up the ultimate contributions of individual active regions to the solar axial dipole moment at the end of the cycle. A potential limitation of the approach is its dependence on the underlying surface flux transport (SFT) model details. We demonstrate by both analytical and numerical methods that the factor relating the initial and ultimate dipole moment contributions of an active region displays a Gaussian dependence on latitude with parameters that only depend on details of the SFT model through the parameter η /Δ u where η is supergranular diffusivity and Δ u is the divergence of the meridional flow on the equator. In a comparison with cycles simulated in the 2 × 2D dynamo model we further demonstrate that the inaccuracies associated with the algebraic method are minor and the method may be able to reproduce the dipole moment values in a large majority of cycles.

Topics & Concepts

DynamoDipoleMoment (physics)PhysicsSolar dynamoMeridional flowEquatorSolar cycleAlgebraic numberLatitudeComputational physicsFlux (metallurgy)Divergence (linguistics)Statistical physicsZonal and meridionalQuantum electrodynamicsClassical mechanicsMathematical analysisDynamo theoryMathematicsAtmospheric sciencesMagnetic fieldQuantum mechanicsChemistrySolar windOrganic chemistryLinguisticsPhilosophyAstronomySolar and Space Plasma DynamicsStellar, planetary, and galactic studiesAstro and Planetary Science
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