Bibcode
Silva-Valio, A.; Lanza, A. F.; Alonso, R.; Barge, P.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 510, id.A25
Fecha de publicación:
2
2010
Revista
Número de citas
99
Número de citas referidas
76
Descripción
Context. As a planet eclipses its parent star, a dark spot on the
surface of the star may be occulted, causing a detectable variation in
the light curve. Aims: We study these light curve variations
during transits and infer the physical characteristics of the stellar
spots. Methods: A total of 77 consecutive transit light curves of
CoRoT-2 were observed with a high temporal resolution of 32 s,
corresponding to an uninterrupted period of 134 days. By analyzing small
intensity variations in the transit light curves, it was possible to
detect and characterize spots on the surface of the star. The model used
simulates planetary transits and enables the inclusion of spots on the
stellar surface with different sizes, intensities (i.e., temperatures),
and positions. Fitting the data with this model, it is possible to infer
the physical characteristics of the spots. Because what is observed is
the stellar flux blocked by the spots, there is a degeneracy between the
spot intensity and area, although the spot radius defines the shape and
width of the signal in the light curve. The model allows up to 9 spots
to be present on the stellar surface within the transit band.
Results: Before the modeling of the spots was performed, the planetary
radius relative to the star radius was estimated by fitting the deepest
transit to minimize the effect of spots. A slightly larger (3%) radius,
0.172 Rstar, resulted instead in the previously reported
0.1667 Rstar. The fitting of the transits yields spots, or
spot groups, of sizes ranging from 0.2 to 0.7 planetary radius,
Rp, with a mean of 0.46 ± 0.11 Rp (~ 100
000 km), resulting in a stellar area covered by spots within the transit
latitudes of 10-20%. The intensity varied from 0.3 to 0.8 of the disk
center intensity, Ic, with a mean of 0.55 ± 0.13
Ic, which can be converted to temperature by assuming
black-body emission for both the photosphere and the spots. Considering
an effective temperature of 5625 K for the stellar photosphere, the mean
spot temperature is 4700 ± 300 K. Conclusions: The spot
model used here was able to estimate the physical characteristics of the
spots on CoRoT-2, such as size and intensity. The spots on CoRoT-2 are
larger and cooler than sunspots, maybe confirming the more active nature
of this star with respect to the Sun. The results presented here are in
agreement with those found for magnetic activity analysis from out of
transit data of the same star.
CoRoT is a space project operated by the French Space Agency, CNES, with
participation of the Science Programme of ESA, ESTEC/RSSD, Austria,
Belgium, Brazil, Germany, and Spain.