2009
DOI: 10.1088/0004-637x/698/1/519
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Transits of Earth-Like Planets

Abstract: Transmission spectroscopy of Earth-like exoplanets is a potential tool for habitability screening. Transiting planets are present-day "Rosetta Stones" for understanding extrasolar planets because they offer the possibility to characterize giant planet atmospheres and should provide an access to biomarkers in the atmospheres of Earth-like exoplanets, once they are detected. Using the Earth itself as a proxy we show the potential and limits of the transiting technique to detect biomarkers on an Earth-analog exop… Show more

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Cited by 332 publications
(401 citation statements)
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“…To save on computation time, Bétrémieux & Kaltenegger (2013) modified the code so that one can choose not to include thermal emission. Although the line opacity database is identical to that in Kaltenegger & Traub (2009), Bétrémieux & Kaltenegger (2013) replaced the original Rayleigh scattering parametrisation, appropriate only for Earth, with a database of Rayleigh scattering cross sections for N2, O2, CO2, and Ar (see their Table 2). They also included new routines to compute optical depths from continuous absorption cross sections, and a new database of ultraviolet and visible absorbers (see their Table 1).…”
Section: Radiative Transfermentioning
confidence: 99%
“…To save on computation time, Bétrémieux & Kaltenegger (2013) modified the code so that one can choose not to include thermal emission. Although the line opacity database is identical to that in Kaltenegger & Traub (2009), Bétrémieux & Kaltenegger (2013) replaced the original Rayleigh scattering parametrisation, appropriate only for Earth, with a database of Rayleigh scattering cross sections for N2, O2, CO2, and Ar (see their Table 2). They also included new routines to compute optical depths from continuous absorption cross sections, and a new database of ultraviolet and visible absorbers (see their Table 1).…”
Section: Radiative Transfermentioning
confidence: 99%
“…Using the projected separation of GJ725AB (≈47 au) and assuming typical masses of ≈0.36 M e and ≈0.3 M e that correspond to their respective spectral types of M3 and M3.5 (Reid & Hawley 2005;Kaltenegger & Traub 2009), their orbital period should be P≈400 years. This corresponds to a tangential velocity of v≈1.75 km s −1 as measured from the center of mass in the case of a circular orbit.…”
Section: Candidate Rv Variable Targetsmentioning
confidence: 99%
“…Assuming a mass of ≈0.58 M e for GJ458A (Gaidos et al 2014) and a mass of ≈0.36 M e for GJ458B that is typical of a field M3 star (Reid & Hawley 2005;Kaltenegger & Traub 2009) and using the projected separation of ≈228 au, we would expect a period of ≈3550 years for the orbit of the GJ458AB system in a case with zero eccentricity. This would be consistent with a maximal RV slope of only ≈1.2 m s −1 yr −1 .…”
Section: Likely Linear Trends In Rv Curvesmentioning
confidence: 99%
“…As more potentially habitable planets are discovered around low-mass stars, a similar analysis as in Section 5 should be undertaken in order to assess the possibility that the planet could in fact be dehydrated. As we may only be able to spectroscopically characterize a few planets with the James Webb Space Telescope (Kaltenegger and Traub, 2009;Seager et al, 2009), prioritization of targets is crucial, and past and present tidal heating will help determine the best planet to observe.…”
Section: Discussionmentioning
confidence: 99%