学术文献库

An activity indicator, which can provide a robust quantitative mapping between the stellar activity and the physical properties of its atmosphere, is important in exploring the physics of activity across spectral types. But the common activity indicators show large variability in their values which makes defining a robust quantitative scale difficult. Millimetre (mm) wavelengths probe the different atmospheric layers within the stellar chromosphere providing a tomographic view of the atmospheric dynamics. The project aims to define a robust mm-based activity indicator for the cool main-sequence stars ($\mathrm{T_{eff}} \sim$ 5000 - 7000 K). We derive the mm-brightness temperature ($\mathrm{T_B(ν)}$) spectral indices ($\mathrm{α_{mm}}$) for cool stars including the Sun using archival data in the 30 - 1000 GHz range. The derived values for $\mathrm{α_{mm}}$ are explored as a function of various physical parameters and empirical power-law functions were derived. $\mathrm{α_{mm}}$ estimates were also compared with other activity indicators. Despite the estimation errors, $\mathrm{α_{mm}}$ values could well distinguish the cool stars, unlike common activity indicators. The low estimation errors on the derived trends of $\mathrm{α_{mm}}$ versus physical parameters suggest that $\mathrm{α_{mm}}$ could be a robust activity indicator. $\mathrm{α_{mm}}$, which is linked to chromospheric thermal stratification and activity in cool stars can well distinguish and physically characterise the stars more robustly than common activity indicators. We emphasise the need for multi-frequency data across the mm-band for stars, with a range of physical parameters and gathered at multiple epochs during activity cycles. This will help explore $\mathrm{α_{mm}}$ in a statistically robust manner and study the emergence of chromospheric heating on the main-sequence.