Exoplanet atmospheres

Detection of CH3C3N in Titan’s Atmosphere

The Astrophysical Journal American Astronomical Society 903:1 (2020) L22-L22

Authors:

Alexander E Thelen, Martin A Cordiner, Conor A Nixon, Véronique Vuitton, Zbigniew Kisiel, Steven B Charnley, Maureen Y Palmer, Nicholas A Teanby, Patrick GJ Irwin

Stable Climates for Temperate Rocky Circumbinary Planets

Journal of Geophysical Research Planets American Geophysical Union (AGU) 125:11 (2020)

The high-energy radiation environment around a 10 Gyr M dwarf: habitable at last?

Astrophysical Journal American Astronomical Society 160:5 (2020) 237

Authors:

Kevin France, Girish Duvvuri, Hilary Egan, Tommi Koskinen, David J Wilson, Allison Youngblood, Cynthia S Froning, Alexander Brown, Julian Alvarado-Gomez, Zachory K Berta-Thompson, Jeremy J Drake, Cecilia Garraffo, Lisa Kaltenegger, Adam F Kowalski, Jeffry L Linsky, ROP Loyd, Pablo JD Mauas, Yamila Miguel, J Sebastian Pineda, Sarah Rugheimer, P Christian Schneider, Feng Tian, Mariela Vieytes

Abstract:

Recent work has demonstrated that high levels of X-ray and UV activity on young M dwarfs may drive rapid atmospheric escape on temperate, terrestrial planets orbiting within the habitable zone. However, secondary atmospheres on planets orbiting older, less active M dwarfs may be stable and present more promising candidates for biomarker searches. In order to evaluate the potential habitability of Earth-like planets around old, inactive M dwarfs, we present new Hubble Space Telescope and Chandra X-ray Observatory observations of Barnard's Star (GJ 699), a 10 Gyr old M3.5 dwarf, acquired as part of the Mega-MUSCLES program. Despite the old age and long rotation period of Barnard's Star, we observe two FUV (δ130 ≈ 5000 s; E130 ≈ 1029.5 erg each) and one X-ray (EX ≈ 1029.2 erg) flares, and we estimate a high-energy flare duty cycle (defined here as the fraction of the time the star is in a flare state) of ~25%. A publicly available 5 Å to 10 μm spectral energy distribution of GJ 699 is created and used to evaluate the atmospheric stability of a hypothetical, unmagnetized terrestrial planet in the habitable zone (rHZ ~ 0.1 au). Both thermal and nonthermal escape modeling indicate (1) the quiescent stellar XUV flux does not lead to strong atmospheric escape: atmospheric heating rates are comparable to periods of high solar activity on modern Earth, and (2) the flare environment could drive the atmosphere into a hydrodynamic loss regime at the observed flare duty cycle: sustained exposure to the flare environment of GJ 699 results in the loss of ≈87 Earth atmospheres Gyr−1 through thermal processes and ≈3 Earth atmospheres Gyr−1 through ion loss processes. These results suggest that if rocky planet atmospheres can survive the initial ~5 Gyr of high stellar activity, or if a second-generation atmosphere can be formed or acquired, the flare duty cycle may be the controlling stellar parameter for the stability of Earth-like atmospheres around old M stars.

Detection of Cyclopropenylidene on Titan with ALMA

(2020)

Authors:

Conor A Nixon, Alexander E Thelen, Martin A Cordiner, Zbigniew Kisiel, Steven B Charnley, Edward M Molter, Joseph Serigano, Patrick GJ Irwin, Nicholas A Teanby, Yi-Jehng Kuan

Future missions related to the determination of the elemental and isotopic composition of Earth, Moon and the terrestrial planets

Space Science Reviews Springer 216:8 (2020) 121

Authors:

Dandouras, Blanc, Fossati, Gerasimov, Guenther, Kislyakova, Lammer, Lin, Marty, Mazelle, Sarah Rugheimer, Scherf, Sotin, Sproß, Tachibana, Wurz, Yamauchi

Abstract:

In this chapter, we review the contribution of space missions to the determination of the elemental and isotopic composition of Earth, Moon and the terrestrial planets, with special emphasis on currently planned and future missions. We show how these missions are going to significantly contribute to, or sometimes revolutionise, our understanding of planetary evolution, from formation to the possible emergence of life. We start with the Earth, which is a unique habitable body with actual life, and that is strongly related to its atmosphere. The new wave of missions to the Moon is then reviewed, which are going to study its formation history, the structure and dynamics of its tenuous exosphere and the interaction of the Moon’s surface and exosphere with the different sources of plasma and radiation of its environment, including the solar wind and the escaping Earth’s upper atmosphere. Missions to study the noble gas atmospheres of the terrestrial planets, Venus and Mars, are then examined. These missions are expected to trace the evolutionary paths of these two noble gas atmospheres, with a special emphasis on understanding the effect of atmospheric escape on the fate of water. Future missions to these planets will be key to help us establishing a comparative view of the evolution of climates and habitability at Earth, Venus and Mars, one of the most important and challenging open questions of planetary science. Finally, as the detection and characterisation of exoplanets is currently revolutionising the scope of planetary science, we review the missions aiming to characterise the internal structure and the atmospheres of these exoplanets.