Global Energetics of Solar Flares: I. Magnetic Energies

Abstract

We present the first part of a project on the global energetics of solar flares and coronal mass ejections (CMEs) that includes about 400 M- and X-class flares observed with AIA and HMI onboard SDO. We calculate the potential energy, free energy, and the flare-dissipated magnetic energy. We calculate these magnetic parameters using two different NLFFF codes: The COR-NLFFF code uses the line-of-sight magnetic field component Bz from HMI to define the potential field, and the 2D coordinates of automatically detected coronal loops in 6 coronal wavelengths from AIA to measure the helical twist of coronal loops caused by vertical currents, while the PHOT-NLFFF code extrapolates the photospheric 3D vector fields. We find agreement between the two codes in the measurement of free energies and dissipated energies within a factor of ≈ 3. The size distributions of magnetic parameters exhibit powerlaw slopes that are approximately consistent with the fractal-diffusive self-organized criticality model. The magnetic parameters exhibit scaling laws for the nonpotential energy, Enp Ep1.02, for the free energy, Efree Ep1.7 and Efree B1.0 L1.5, for the dissipated energy, Ediss Ep1.6 and Ediss Efree0.9, and the energy dissipation volume, V Ediss1.2. The potential energies vary in the range of Ep = 1 × 1031 - 4 × 1033 erg, while the free energy has a ratio of Efree/Ep ≈ 1%-25%. The Poynting flux amounts to Fflare ≈ 5 × 108 - 1010 erg cm-2 s-1 during flares, which averages to FAR ≈ 6 × 106 erg cm-2 s-1 during the entire observation period and is comparable with the coronal heating rate requirement in active regions.