Abstract
The direct detection of exoplanets has been the subject of intensive research in the recent years. Data obtained with future high-contrast imaging instruments optimized for giant planets direct detection are strongly limited by the speckle noise. Specific observing strategies and data analysis methods, such as angular and spectral differential imaging, are required to attenuate the noise level and possibly detect the faint planet flux. Even though these methods are very efficient at suppressing the speckles, the photometry of the faint planets is dominated by the speckle residuals. The determination of the effective temperature and surface gravity of the detected planets from photometric measurements in different bands is then limited by the photometric error on the planet flux. In this work we investigate this photometric error and the consequences on the determination of the physical parameters of the detected planets. We perform detailed end-to-end simulation with the CAOS-based Software Package for SPHERE to obtain realistic data representing typical observing sequences in Y, J, H and Ks bands with a high contrast imager. The simulated data are used to measure the photometric accuracy as a function of contrast for planets detected with angular and spectral+angular differential methods. We apply this empirical accuracy to study the characterization capabilities of a high-contrast differential imager. We show that the expected photometric performances will allow the detection and characterization of exoplanets down to the Jupiter mass at angular separations of 1.0" and 0.2" respectively around high mass and low mass stars with 2 observations in different filter pairs. We also show that the determination of the planets physical parameters from photometric measurements in different filter pairs is essentialy limited by the error on the determination of the surface gravity.
Highlights
Since the detection of the first exoplanet orbiting a main-sequence star, 51 Peg, a large population of these objects has been discovered
We investigate the photometric limitations in highcontrast data obtained at different wavelengths with a dual-band imager such as infrared dual imaging spectrograph (IRDIS), and we study how this translates in terms of characterization of planetary-mass objects
If we compare these 1σ noise levels to those derived for the IRDIS long slit spectroscopy (LSS) mode (Vigan et al 2008), we see that they are comparable between angular differential imaging (ADI) and LSS
Summary
Since the detection of the first exoplanet orbiting a main-sequence star, 51 Peg, a large population of these objects has been discovered. The Gemini planet imager (GPI) for Gemini South (Macintosh et al 2006) and the spectro-polarimetric high-contrast exoplanet research (SPHERE) for the European Southern Observatory (ESO) Very Large Telescope (VLT) (Beuzit et al 2006) are the two leading instruments of that category These will both start operation in 2011, along with the high-contrast coronagraphic imager for adaptive optics (HiCIAO) for Subaru (Hodapp et al 2008). These will aim to detect exoplanets down to the Jupiter mass (MJup) around nearby young stars by reaching contrast values of 15–17.5 mag (10−6–10−7) at angular separations of ∼0.1 arcsec Both GPI and SPHERE will incorporate diffraction-limited integral field spectrographs (IFSs) in the near-infrared, allowing us to obtain images simultaneously at several wavelengths.
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