Global Energetics of Solar Flares: II. Thermal Energies

Abstract

We present the second part of a project on the global energetics of solar flares and CMEs that includes about 400 M- and X-class flares observed with AIA/SDO during the first 3.5 years of its mission. In this Paper II we compute the differential emission measure (DEM) distribution functions and associated multi-thermal energies, using a spatially-synthesized Gaussian DEM forward-fitting method. The multi-thermal DEM function yields a significantly higher (by an average factor of ≈ 14), but more comprehensive (multi-)thermal energy than an isothermal energy estimate from the same AIA data. We find a statistical energy ratio of Eth/Ediss ≈ 2\%-40\% between the multi-thermal energy Eth and the magnetically dissipated energy Ediss, which is an order of magnitude higher than the estimates of Emslie et al.~2012. For the analyzed set of M and X-class flares we find the following physical parameter ranges: L=108.2-109.7 cm for the length scale of the flare areas, Tp=105.7-107.4 K for the DEM peak temperature, Tw=106.8-107.6 K for the emission measure-weighted temperature, np=1010.3-1011.8 cm-3 for the average electron density, EMp=1047.3-1050.3 cm-3 for the DEM peak emission measure, and Eth=1026.8-1032.0 erg for the multi-thermal energies. The deduced multi-thermal energies are consistent with the RTV scaling law Eth,RTV = 7.3 × 10-10 \ Tp3 Lp2, which predicts extremal values of Eth,max ≈ 1.5 × 1033 erg for the largest flare and Eth,min ≈ 1 × 1024 erg for the smallest coronal nanoflare. The size distributions of the spatial parameters exhibit powerlaw tails that are consistent with the predictions of the fractal-diffusive self-organized criticality model combined with the RTV scaling law.