STITCH: A Subgrid-Scale Model for Energy Buildup in the Solar Corona

TL;DR

This paper introduces STITCH, a subgrid-scale model for simulating energy buildup and filament channel formation in the solar corona, improving efficiency and realism in MHD simulations of solar eruptions.

Contribution

STITCH provides a physics-based, reduced model for helicity condensation, enabling efficient and accurate simulation of filament channels and eruptive structures in the solar corona.

Findings

STITCH accurately reproduces full helicity-condensation dynamics.

The model reduces computational time and spatial resolution requirements.

It effectively forms localized filament channels and energizes complex flux distributions.

Abstract

The solar corona routinely exhibits explosive activity, in particular coronal mass ejections and their accompanying eruptive flares, that have global-scale consequences. These events and their smaller counterparts, coronal jets, originate in narrow, sinuous filament channels. The key processes that form and evolve the channels operate on still smaller spatial scales and much longer time scales, culminating in a vast separation of characteristic lengths and times that govern these explosive phenomena. In this article, we describe implementation and tests of an efficient subgrid-scale model for generating eruptive structures in magnetohydrodynamics (MHD) coronal simulations. STITCH -- STatistical InjecTion of Condensed Helicity -- is a physics-based, reduced representation of helicity condensation: a process wherein small-scale vortical surface convection forms ubiquitous current sheets, and pervasive reconnection across the sheets mediates an inverse cascade of magnetic helicity and free energy, thereby forming the filament channels. STITCH abstracts these complex processes into a single new term, in the MHD Ohm's law and induction equation, which directly injects tangential magnetic flux into the low corona. We show that this approach is in very good agreement with a full helicity-condensation calculation that treats all of the dynamics explicitly, while enabling substantial reductions in temporal duration especially, but also in spatial resolution. In addition, we illustrate the flexibility of STITCH at forming localized filament channels and at energizing complex surface flux distributions that have sinuous boundaries. STITCH is simple to implement and computationally efficient, making it a powerful new technique for event-based, data-driven modeling of solar eruptions.