Coronal Mass Ejection (CME) Activity of Low Mass M Stars as An Important Factor for The Habitability of Terrestrial Exoplanets. II. CME-Induced Ion Pick Up of Earth-like Exoplanets in Close-In Habitable Zones

Lämmer, H.; Lichtenegger, Herbert; Kulikov, Yu. N.; Grießmeier, J.-M.; Terada, Naoki; Еркаев, Н. В.; Biernat, H. K.; Khodachenko, M. L.; Ribas, I.; Penz, T.; Selsis, F.

doi:10.1089/ast.2006.0128

Cited by 316 publications

(303 citation statements)

References 88 publications

(132 reference statements)

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“…Many other critical phenomena were also left out, such as atmospheric erosion by flaring, stellar activity, and magnetic dynamo generation Lammer et al, 2007Lammer et al, , 2010Tian, 2009;Segura et al, 2010;Driscoll and Olson, 2011). Tidal heating provides an interesting counterbalance to atmospheric erosion, as it may increase the outgassing rates and maintain a permanent atmosphere.…”

Section: Discussionmentioning

confidence: 99%

“…The recently discovered Y dwarf (which is not a star) WISEP J1828+2650 (Cushing et al, 2011), with an effective temperature below 300 K, is an example of such a primary. For warmer stars, HZs may still be close enough in that nonradiative processes may impact habitability, such as stellar flaring (e.g., Khodachenko et al, 2007;Lammer et al, 2007Lammer et al, , 2010Tian, 2009;Segura et al, 2010), decreased initial volatile inventory (Lissauer, 2007;Raymond et al, 2007), or tidal effects (e.g., Kasting et al, 1993;Joshi et al, 1997;Correia et al, 2008;Jackson et al, 2008a;Barnes et al, 2009a;Heller et al, 2011). As the HZ of our Sun is too distant for these phenomena to affect Earth, we can currently only explore their role theoretically; consequently, many scientists consider close-in planets less favorable candidates for habitability.…”

Section: Introductionmentioning

confidence: 99%

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Tidal Venuses: Triggering a Climate Catastrophe via Tidal Heating

et al. 2013

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Traditionally, stellar radiation has been the only heat source considered capable of determining global climate on long timescales. Here, we show that terrestrial exoplanets orbiting low-mass stars may be tidally heated at highenough levels to induce a runaway greenhouse for a long-enough duration for all the hydrogen to escape. Without hydrogen, the planet no longer has water and cannot support life. We call these planets ''Tidal Venuses'' and the phenomenon a ''tidal greenhouse.'' Tidal effects also circularize the orbit, which decreases tidal heating. Hence, some planets may form with large eccentricity, with its accompanying large tidal heating, and lose their water, but eventually settle into nearly circular orbits (i.e., with negligible tidal heating) in the habitable zone (HZ). However, these planets are not habitable, as past tidal heating desiccated them, and hence should not be ranked highly for detailed follow-up observations aimed at detecting biosignatures. We simulated the evolution of hypothetical planetary systems in a quasi-continuous parameter distribution and found that we could constrain the history of the system by statistical arguments. Planets orbiting stars with masses < 0.3 M Sun may be in danger of desiccation via tidal heating. We have applied these concepts to Gl 667C c, a *4.5 M Earth planet orbiting a 0.3 M Sun star at 0.12 AU. We found that it probably did not lose its water via tidal heating, as orbital stability is unlikely for the high eccentricities required for the tidal greenhouse. As the inner edge of the HZ is defined by the onset of a runaway or moist greenhouse powered by radiation, our results represent a fundamental revision to the HZ for noncircular orbits. In the appendices we review (a) the moist and runaway greenhouses, (b) hydrogen escape, (c) stellar mass-radius and mass-luminosity relations, (d) terrestrial planet mass-radius relations, and (e) linear tidal theories.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tidal Venuses: Triggering a Climate Catastrophe via Tidal Heating

et al. 2013

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“…As the stellar spectrum of the M-star is redshifted compared with the solar one, Rayleigh scattering (proportional to λ −4 ) is decreased, as well as the albedo of the planet. The increased magnetic activity of M-stars may lead to a stronger stellar wind, more stellar flares and possibly more atmospheric erosion (Lammer et al 2007;Penz et al 2008). Joshi et al (1997) and Wordsworth et al (2011) have used three-dimensional simulations to estimate the climate and habitability of terrestrial planets in orbit around M stars.…”

Section: Habitable Exoplanets Around M-type Starsmentioning

confidence: 99%

Spectroscopy of planetary atmospheres in our Galaxy

Tinetti

Encrenaz

Coustenis

2013

Astron Astrophys Rev

128

111

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About 20 years after the discovery of the first extrasolar planet, the number of planets known has grown by three orders of magnitude, and continues to increase at neck breaking pace. For most of these planets we have little information, except for the fact that they exist and possess an address in our Galaxy. For about one third of them, we know how much they weigh, their size and their orbital parameters. For less than 20, we start to have some clues about their atmospheric temperature and composition. How do we make progress from here?We are still far from the completion of a hypothetical Hertzsprung-Russell diagram for planets comparable to what we have for stars, and today we do not even know whether such classification will ever be possible or even meaningful for planetary objects. But one thing is clear: planetary parameters such as mass, radius and temperature alone do not explain the diversity revealed by current observations. The chemical composition of these planets is needed to trace back their formation history and evolution, as happened for the planets in our Solar System. As in situ measurements are and will remain off-limits for exoplanets, to study their chemical composition we will have to rely on remote sensing spectroscopic observations of their gaseous envelopes.

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“…A suggestion of terrestrial planets with sulfur cycles dominating over carbon cycles is described in Kaltenegger & Sasselov (2010). Others have attempted to quantify the atmospheric escape of Earths and super Earths, with little success due to the unknown initial mass and star's activity history (e.g., Lammer et al 2007).…”

Section: Super Earth Atmospheresmentioning

confidence: 99%

Exoplanet atmospheres: A theoretical outlook

Seager

2010

Proc. IAU

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Abstract. With over two dozen exoplanet atmospheres observed today, the field of exoplanet atmospheres is solidly established. The highlights of exoplanet atmosphere studies include: detection of molecular spectral features; constraints on atmospheric vertical temperature structure; detection of day-night temperature gradients; and a new numerical approach to atmosphere temperature and abundance retrieval. As hot Jupiter observations and interpretation are maturing, the next frontier is super Earth atmospheres. Theoretical models of super Earth atmospheres are moving forward with observational hopes pinned on the James Webb Space Telescope, scheduled for launch in 2014. Further in the future lies direct imaging attempts to answer the enigmatic and ancient question, "Are we alone?" via atmospheric biosignatures.

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Coronal Mass Ejection (CME) Activity of Low Mass M Stars as An Important Factor for The Habitability of Terrestrial Exoplanets. II. CME-Induced Ion Pick Up of Earth-like Exoplanets in Close-In Habitable Zones

Cited by 316 publications

References 88 publications

Tidal Venuses: Triggering a Climate Catastrophe via Tidal Heating

Tidal Venuses: Triggering a Climate Catastrophe via Tidal Heating

Spectroscopy of planetary atmospheres in our Galaxy

Exoplanet atmospheres: A theoretical outlook

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