The GTC exoplanet transit spectroscopy survey

Nortmann, L.; Pallé, E.; Murgas, F.; Dreizler, S.; Iro, Nicolas; Cabrera-Lavers, A.

doi:10.1051/0004-6361/201527323

Cited by 45 publications

(48 citation statements)

References 38 publications

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“…Previous ground-based observations of the transit of HAT-P-32b in the optical wavelengths (Gibson et al 2013;Zhao et al 2014;Mallonn & Strassmeier 2016;Nortmann et al 2016) did not find evidence of spectral modulations due to molecules. Our cloud top pressure is consistent with their measurements within 1σ, hence the water detection in the infrared is not controversial.…”

Section: Comparison With Other Observationsmentioning

confidence: 66%

“…HAT-P-32b is one of the most inflated exoplanets discovered, being less massive than Jupiter (M M 0.79 p J u p = ) but having almost twice its radius (R R 1.789 p J u p = ). The atmosphere of HAT-P-32b has been observed with ground-based instruments in the optical wavelengths, revealing a featureless transmission spectrum (Gibson et al 2013;Zhao et al 2014;Mallonn & Strassmeier 2016;Nortmann et al 2016). In addition, Zhao et al (2014) suggested the presence of a thermal inversion in the atmosphere of HAT-P-32bto interpret eclipse observations.…”

Section: Introductionmentioning

confidence: 99%

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Near-IR Transmission Spectrum of HAT-P-32b using HST/WFC3

Damiano

Morello

Tsiaras

et al. 2017

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We report here the analysis of the near-infrared transit spectrum of the hot Jupiter HAT-P-32b, which was recorded with the Wide Field Camera 3 (WFC3) on board the Hubble Space Telescope. HAT-P-32bis one of the most inflated exoplanets discovered, making it an excellent candidate for transit spectroscopic measurements. To obtain the transit spectrum, we have adopted different analysis methods, both parametric and non-parametric (Independent Component Analysis, ICA), and compared the results. The final spectra are all consistent within 0.5σ. The uncertainties obtained with ICA are larger than those obtained with the parametric method by a factor of ∼1.6-1.8. This difference is the tradeoff for higher objectivity due to the lack of any assumption about the instrument systematics compared to the parametric approach. The ICA error bars are therefore worst-case estimates. To interpret the spectrum of HAT-P-32b we used  -REx, our fully Bayesian spectral retrieval code. As for other hot Jupiters, the results are consistent with the presence of water vapor (log H O 3.45 2 1.65, clouds (top pressure between 5.16 and 1.73 bar). Spectroscopic data over a broader wavelength range are needed to de-correlate the mixing ratio of water vapor from clouds and identify other possible molecular species in the atmosphere of HAT-P-32b.

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Section: Comparison With Other Observationsmentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Near-IR Transmission Spectrum of HAT-P-32b using HST/WFC3

Damiano

Morello

Tsiaras

et al. 2017

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“…As in Nortmann et al (2016), the Bayesian Information Criterion (BIC) was used to select the best light curve model. The BIC penalizes a high χ 2 value and/or the number of free parameters used in the fitting procedure; the model that presents the lowest BIC is the one selected.…”

Section: Model Selectionmentioning

confidence: 99%

“…All the tested models present a synthetic transit model with a time dependency to reproduce a second-order color effect not corrected by the differential photometry, and a FWHM dependent polynomial to model the systematic effects produced by seeing variations. The FWHM correction was introduced because seeing variations affected the number of pixels in which the major part of the stellar flux is contained, and this pixel-dependent effect will act as a systematic correlated with FWHM (see Nortmann et al 2016;Chen et al 2017). With a slit 40 arcsec in width, the flux losses produced by not being able to measure the flux contained in the wings of the spectral profile are negligible.…”

Section: Model Selectionmentioning

confidence: 99%

“…The principle of transmission spectroscopy is to measure the change in the planetary radius at different wavelengths during a transit event, and to use this change to infer the presence of particular components of the exoplanet atmosphere. Because of their relatively big atmospheric scale heights, hot Jupiters are excellent targets for atmospheric detection from the ground and they are the main targets of our survey (e.g., Murgas et al 2014;Parviainen et al 2016;Pallé et al 2016;Nortmann et al 2016;Chen et al 2017).…”

Section: Introductionmentioning

confidence: 99%

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The GTC exoplanet transit spectroscopy survey

Murgas

Πάλλη

Parviainen

et al. 2017

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Context. Transiting planets offer an excellent opportunity for characterizing the atmospheres of extrasolar planets under very different conditions from those found in our solar system. Aims. We are currently carrying out a ground-based survey to obtain the transmission spectra of several extrasolar planets using the 10 m Gran Telescopio Canarias. In this paper we investigate the extrasolar planet WASP-48b, a hot Jupiter orbiting around an F-type star with a period of 2.14 days. Methods. We obtained long-slit optical spectroscopy of one transit of WASP-48b with the Optical System for Imaging and lowIntermediate-Resolution Integrated Spectroscopy (OSIRIS) spectrograph. We integrated the spectrum of WASP-48 and one reference star in several channels with different wavelength ranges, creating numerous color light curves of the transit. We fit analytic transit curves to the data taking into account the systematic effects present in the time series in an effort to measure the change of the planetto-star radius ratio (R p /R s ) across wavelength. The change in transit depth can be compared with atmosphere models to infer the presence of particular atomic or molecular compounds in the atmosphere of WASP-48b. Results. After removing the transit model and systematic trends to the curves we reached precisions between 261 ppm and 455-755 ppm for the white and spectroscopic light curves, respectively. We obtained R p /R s uncertainty values between 0.8 × 10 −3 and 1.5 × 10 −3 for all the curves analyzed in this work. The measured transit depth for the curves made by integrating the wavelength range between 530 nm and 905 nm is in agreement with previous studies. We report a relatively flat transmission spectrum for WASP-48b with no statistical significant detection of atmospheric species, although the theoretical models that fit the data more closely include TiO and VO.

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Near‐ultraviolet transit photometry of HAT‐P‐32 b with the Large Binocular Telescope: Silicate aerosols in the planetary atmosphere

Mallonn

Wakeford

2017

Astron Nachr

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Broad-band exoplanet transit photometry can characterize the planetary atmosphere when observed at multiple selected filters. This observing technique can reveal gradients in the spectra of extrasolar planets, for example, the slope of decreasing opacity from short to long optical wavelengths caused by aerosol scattering. In this work, we observed a transit of the hot Jupiter HAT-P-32 b in the shortest wavelength possible from the ground using the Large Binocular Telescope (LBT). The data comprise the best quality ground-based U-band measurement taken so far of an exoplanet transit. Compared to broad-band observations of intermediate and long optical wavelengths published previously, a clear scattering slope in the planetary transmission spectrum is revealed. Most likely, the scattering particles are magnesium silicate aerosols larger than 0.1 μm. We define a spectral index to compare this scattering feature of HAT-P-32 b with published results of other exoplanets. It turns out to be very typical in amplitude within the compared sample. Furthermore, we searched for correlation in this sample of the spectral index with planetary equilibrium temperature, surface acceleration, and stellar activity indicator, but could not find any.

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The GTC exoplanet transit spectroscopy survey

Cited by 45 publications

References 38 publications

Near-IR Transmission Spectrum of HAT-P-32b using HST/WFC3

Near-IR Transmission Spectrum of HAT-P-32b using HST/WFC3

The GTC exoplanet transit spectroscopy survey

Near‐ultraviolet transit photometry of HAT‐P‐32 b with the Large Binocular Telescope: Silicate aerosols in the planetary atmosphere

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