Observational signs of limited flare area variation and peak flare temperatures estimations in main-sequence flaring stars

Abstract

In the study of stellar flares, traditional method of calculating total energy emitted in the continuum assumes the emission originating from a narrow chromospheric condensation region with a constant temperature of 10000 K and variable flare area. However, based on multicolor data from 7 new flares observed in Biak\'ow and Shumen observatory and 8 flares from (Howard et al., 2020) observed on 10 main-sequence stars (spectral types M5.5V to K5V) we show that flare areas had a relative change in the range of 10% - 61% (for more than half of the flares this value did not exceed 30%) throughout the events except for the impulsive phase, and had values starting from 50 +/- 30 ppm to 300 +/- 150 ppm for our new flares and from 380 +/- 200 ppm to 7600 +/- 3000 ppm from (Howard et al., 2020) data, while their temperature increased on average by the factor 2.5. The peak flare temperatures for our seven observed flares ranged from 5700 +/- 450 K to 17500 +/- 10050 K. Five of these flares had their temperatures estimated using the Johnson-Kron-Cousins B filter alongside TESS data, one flare was analyzed using the SLOAN g' and r' bandpasses, and another was evaluated using both the SLOAN g' and r' bandpasses and TESS data. Using flare temperature and area from our data and data from Howard et al., 2020, along with the physical parameters of stars where the flares occurred, we developed a semi-empirical grid that correlates a star's effective temperature and flare amplitude in TESS data with the flare's peak temperature. This allows interpolation of a flare's peak temperature based on the star's effective temperature (ranging from 2700 K to 4600 K) and flare amplitude from TESS observations. Applying this grid to 42257 flares from TESS survey, we estimated peak flare temperatures between 5700 K and 38300 K, with most flares showing peak black-body temperatures around 11100 +/- 2400 K.