On the role of meridional flows in flux transport dynamo models

TL;DR

This study investigates how different meridional flow patterns in the solar convection zone influence the solar magnetic cycle and field parity, using numerical flux transport dynamo models to match observed solar features.

Contribution

It demonstrates that multicellular meridional flows can reproduce the solar 22-year cycle and dipolar parity, providing insights into the solar dynamo mechanism and flow configurations.

Findings

Multicellular flows speed up the solar cycle.

Adding cells in radius increases the cycle period.

Multicellular flows favor quadrupolar parity.

Abstract

The Sun is a magnetic star whose magnetism and cyclic activity is linked to the existence of an internal dynamo. We aim to understand the establishment of the solar magnetic 22-yr cycle, its associated butterfly diagram and field parity selection through numerical simulations of the solar global dynamo. Inspired by recent observations and 3D simulations that both exhibit multicellular flows in the solar convection zone, we seek to characterise the influence of various profiles of circulation on the behaviour of solar mean-field dynamo models. We are using 2-D mean field flux transport Babcock-Leighton numerical models in which we test several types of meridional flows: 1 large single cell, 2 cells in radius and 4 cells per hemisphere. We confirm that adding cells in latitude tends to speed up the dynamo cycle whereas adding cells in radius more than triples the period. We find that the cycle period in the four cells model is less sensitive to the flow speed than in the other simpler meridional circulation profiles studied. Moreover, our studies show that adding cells in radius or in latitude seems to favour the parity switching to a quadrupolar solution. According to our numerical models, the observed 22-yr cycle and dipolar parity is easily reproduced by models including multicellular meridional flows. On the contrary, the resulting butterfly diagram and phase relationship between the toroidal and poloidal fields are affected to a point where it is unlikely that such multicellular meridional flows persist for a long period of time inside the Sun, without having to reconsider the model itself.