Statistical Study of Emerging Flux Regions and the Upper Atmosphere Response

Abstract

We statistically study the property of emerging flux regions (EFRs) and the upper solar atmosphere response to the flux emergence by using data from the Helioseismic and Magnetic Imager (HMI) and the Atmospheric Imaging Assembly (AIA) on board the Solar Dynamics Observatory (SDO). Parameters including the total emerged flux, the flux growth rate, the maximum area, the duration of the emergence and the separation speed of the opposite polarities are adopted to delineate the property of the EFRs. The response of the upper atmosphere is addressed by the response of the atmosphere at different wavelengths (and thus at different temperatures). According to our results, the total emerged fluxes are in the range of (0.44 -- 11.2)×1019 Mx while the maximum area ranges from 17 to 182 arcsec2. The durations of the emergence are between 1 and 12 hours, which are positively correlated to both the total emerged flux and the maximum area. The maximum distances between the opposite polarities are 7 -- 25 arcsec and are also correlated to the duration positively. The separation speeds are from 0.05 to 1.08 km s-1, negatively correlated to the duration. The derived flux growth rates are (0.1 -- 1.3)×1019 Mx hr-1, which are positively correlated to the total emerging flux. The upper atmosphere responds to the flux emergence in the 1600\ chromospheric line first, and then tens and hundreds of seconds later, in coronal lines, such as the 171\ (T=105.8 K) and 211\ (T=106.3 K) lines almost simultaneously, suggesting the successively heating of atmosphere from the chromosphere to the corona.