The solar dynamo begins near the surface

Article

Vasil, Geoffrey M.; Lecoanet, Daniel; Augustson, Kyle; Burns, Keaton J.; Oishi, Jeffrey S.; Brown, Benjamin P.; Brummell, Nicholas; Julien, Keith

Heriot Watt University; University of Edinburgh; Northwestern University; Northwestern University; Massachusetts Institute of Technology (MIT); Simons Foundation; Flatiron Institute; University of Colorado System; University of Colorado Boulder; University of Colorado System; University of Colorado Boulder

Nature

0028-4283

10.1038/s41586-024-07315-1

2024-05-23

The magnetic dynamo cycle of the Sun features a distinct pattern: a propagating region of sunspot emergence appears around 30 degrees latitude and vanishes near the equator every 11 years (ref. 1 ). Moreover, longitudinal flows called torsional oscillations closely shadow sunspot migration, undoubtedly sharing a common cause 2 . Contrary to theories suggesting deep origins of these phenomena, helioseismology pinpoints low-latitude torsional oscillations to the outer 5-10% of the Sun, the near-surface shear layer 3,4 . Within this zone, inwardly increasing differential rotation coupled with a poloidal magnetic field strongly implicates the magneto-rotational instability 5,6 , prominent in accretion-disk theory and observed in laboratory experiments 7 . Together, these two facts prompt the general question: whether the solar dynamo is possibly a near-surface instability. Here we report strong affirmative evidence in stark contrast to traditional models 8 focusing on the deeper tachocline. Simple analytic estimates show that the near-surface magneto-rotational instability better explains the spatiotemporal scales of the torsional oscillations and inferred subsurface magnetic field amplitudes 9 . State-of-the-art numerical simulations corroborate these estimates and reproduce hemispherical magnetic current helicity laws 10 . The dynamo resulting from a well-understood near-surface phenomenon improves prospects for accurate predictions of full magnetic cycles and space weather, affecting the electromagnetic infrastructure of Earth. Simple analytic estimates and detailed numerical calculations show that the solar dynamo begins near the surface, rather than at the much-deeper tachocline.