Inferring magnetic helicity spectrum in spherical domains: the method and example applications

TL;DR

This paper introduces a new formalism to infer magnetic helicity spectra directly from spherical magnetic field observations, accounting for sign changes across the Sun's equator, with applications to solar and stellar magnetic studies.

Contribution

The authors develop a spherical geometry method to determine magnetic helicity spectra from magnetic field data, avoiding gauge issues and enabling direct observational analysis.

Findings

The method accurately retrieves helicity spectra from analytical models.

Application to MHD simulations shows excellent agreement with known spectra.

Analysis of solar magnetic data reveals bihelical helicity signatures.

Abstract

Obtaining observational constraints on the role of turbulent effects for the solar dynamo is a difficult, yet crucial, task. Without such knowledge, the full picture of the operation mechanism of the solar dynamo cannot be formed. The magnetic helicity spectrum provides important information about the $\alpha$ effect. Here we demonstrate a formalism in spherical geometry to infer magnetic helicity spectra directly from observations of the magnetic field, taking into account the sign change of magnetic helicity across the Sun's equator. Using an angular correlation function of the magnetic field, we develop a method to infer spectra for magnetic energy and helicity. The retrieval of the latter relies on a fundamental definition of helicity in terms of linkage of magnetic flux. We apply the two-scale approach, previously used in Cartesian geometry, to spherical geometry for systems where a sign reversal of helicity is expected across the equator at both small and large scales. We test the method by applying it to an analytical model of a fully helical field, and to magneto-hydrodynamic simulations of a turbulent dynamo. The helicity spectra computed from the vector potential available in the models are in excellent agreement to the spectra computed solely from the magnetic field using our method. In a next test, we use our method to obtain the helicity spectrum from a synoptic magnetic field map corresponding to a Carrington rotation. We observe clear signs of a bihelical spectrum of magnetic helicity. Our formalism makes it possible to infer magnetic helicity in spherical geometry, without the necessity of computing the magnetic vector potential. This has the advantage of being gauge invariant. It has many applications in solar and stellar observations, but can also be used to analyze global magnetoconvection models of stars and compare them with observations.