P32B-01
Characterizing Pale Blue Dots Around FGKM Stars

Wednesday, 16 December 2015: 11:20
2012 (Moscone West)
Sarah Rugheimer, University of St. Andrews, St. Andrews, United Kingdom; Simons Foundation, Collaboration on the Origins of Life, New York, NY, United States, Lisa Kaltenegger, Cornell University, Ithaca, NY, United States, Dimitar D. Sasselov, Harvard University, Astronomy, Cambridge, MA, United States and Antigona Segura, Universidad Nacional Autonoma de Mexico, Instituto de Ciencias Nucleares, Mexico City, Mexico
Abstract:
Exoplanet characterization of small rocky worlds will be a main focus in the coming decades. For future telescopes like JWST and UVOIR/HDST, an exoplanet’s host star will influence our ability to detect and interpret spectral features, including biosignatures. We present a complete suit of stellar models and a grid of model atmospheres for Earth-like planets at equivalent stages of geological evolution in their HZ for stellar effective temperature from Teff = 2300K to 7000K, sampling the entire FGKM stellar type range. Since M dwarfs are simultaneously the most numerous in the universe, the most active, and the most likely stars to host terrestrial exoplanets, we focus in particular on the range of UV emission possible in each sub M spectral class. The UV emission from a planet's host star dominates the photochemistry and thus the resultant observable spectral features of the planet. Using the latest UV spectra obtained by HST and IUE we model the effect of stellar activity on Earth-like planets. We also model the amount of UV flux reaching the surface for Earth-like planets at various geological epochs ranging from a pre-biotic world through the rise of oxygen and for Earth-like planets orbiting FGKM stars at equivalent stages of evolution. When modeling the remotely detectable spectra of these planets we focus on the primary detectable atmospheric features that indicate habitability on Earth, namely: H2O, CO2, O3, CH4, N2O and CH3Cl. We model the emergent as well as transit spectra of Earth-like planets orbiting our grid of FGKM stars in the VIS/NIR (0.4 – 4 μm) and the IR (5 – 20 μm) range as input for future missions like JWST and concepts like UVOIR/HDST.