Bibcode
García-Muñoz, A.; Zapatero Osorio, M. R.; Barrena, R.; Montañés-Rodríguez, P.; Martín, E. L.; Pallé, E.
Bibliographical reference
The Astrophysical Journal, Volume 755, Issue 2, article id. 103 (2012).
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8
2012
Journal
Citations
77
Refereed citations
72
Description
It has been posited that lunar eclipse observations may help predict the
in-transit signature of Earth-like extrasolar planets. However, a
comparative analysis of the two phenomena addressing in detail the
transport of stellar light through the planet's atmosphere has not yet
been presented. Here, we proceed with the investigation of both
phenomena by making use of a common formulation. Our starting point is a
set of previously unpublished near-infrared spectra collected at various
phases during the 2008 August lunar eclipse. We then take the
formulation to the limit of an infinitely distant observer in order to
investigate the in-transit signature of the Earth-Sun system as being
observed from outside our solar system. The refraction bending of
sunlight rays that pass through Earth's atmosphere is a critical factor
in the illumination of the eclipsed Moon. Likewise, refraction will have
an impact on the in-transit transmission spectrum for specific
planet-star systems depending on the refractive properties of the
planet's atmosphere, the stellar size, and the planet's orbital
distance. For the Earth-Sun system, at mid-transit, refraction prevents
the remote observer's access to the lower ~12-14 km of the atmosphere
and, thus, also to the bulk of the spectroscopically active atmospheric
gases. We demonstrate that the effective optical radius of the Earth
in-transit is modulated by refraction and varies by ~12 km from
mid-transit to internal contact. The refractive nature of atmospheres, a
property which is rarely accounted for in published investigations, will
pose additional challenges to the characterization of Earth-like
extrasolar planets. Refraction may have a lesser impact for Earth-like
extrasolar planets within the habitable zone of some M-type stars.
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Galaxies in the universe can be located in different environments, some of them are isolated or in low density regions and they are usually called field galaxies. The others can be located in galaxy associations, going from loose groups to clusters or even superclusters of galaxies. One of the foremost challenges of the modern Astrophysics is to
Jairo
Méndez Abreu