Characterizing Exoplanetary Atmospheres at High Resolution with SPIRou: Detection of Water on HD 189733 b

Boucher, Anne; Darveau-Bernier, Antoine; Pelletier, Sonia; Lafrenière, David; Artigau, Étienne; Cook, Neil J.; Allart, R.; Radica, Michael; Doyon, René; Benneke, Björn; Arnold, L.; Bonfils, X.; Bourrier, V.; Cloutier, Ryan; Silva, João Gomes da; Deibert, Emily; Delfosse, X.; Donati, J.‐F.; Ehrenreich, D.; Figueira, P.; Forveille, T.; Fouqué, P.; Gagné, Jonathan; Gaidos, Eric; Hébrard, G.; Jayawardhana, Ray; Klein, Baptiste; Martins, J. H. C.; Martioli, Eder; Moutou, C.; Santos, N. C.

doi:10.3847/1538-3881/ac1f8e

Cited by 35 publications

(32 citation statements)

References 101 publications

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“…HRCCS was developed in the near infrared, in order to study exoplanets in transmission and thermal emission (e.g. Snellen et al 2010;Brogi et al 2012Brogi et al , 2016Birkby et al 2013Birkby et al , 2017Casasayas-Barris et al 2019;Webb et al 2020;Boucher et al 2021), and it has only recently been applied in the optical for ultra-hot Jupiters such as Kelt-9 b (e.g. Yan & Henning 2018;Hoeijmakers et al 2018bHoeijmakers et al , 2019Pino et al 2020) and Wasp-76 b (e.g.…”

Section: Adaptations For Reflection Hrccsmentioning

confidence: 99%

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Spring

Birkby

Pino

et al. 2022

A&A

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Context. The extreme contrast ratios between stars and their planets at optical wavelengths make it challenging to isolate the light reflected by exoplanet atmospheres. Yet, these reflective properties reveal key processes occurring in the atmospheres, and they also span wavelengths that include the potential O2 biosignature. High resolution cross-correlation spectroscopy (HRCCS) offers a robust avenue for developing techniques to extract exoplanet reflection spectra. Aims. We aimed to extract the optical reflected light spectrum of the non-transiting hot Jupiter 51 Pegasi b by adapting techniques designed to remove tellurics in infrared HRCCS to instead remove optical stellar lines. Importantly, we investigated the as of yet neglected impact of the broadening of the reflected host star spectrum due to the difference between the stellar rotation and the planet’s orbital velocity. Methods. We used 484, R = 115 000 optical spectra of 51 Pegasi b from HARPS-N and HARPS, which we aligned to the exact stellar rest frame, in order to effectively remove the contaminating host star. However, some stellar residuals remained, likely due to stellar activity. We cross-correlated with an appropriately broadened synthetic stellar model to search for the planet’s Doppler-shifting spectrum. Results. We detect no significant reflected light from 51 Pegasi b, and report a signal-to-noise (S∕N) = 3 upper limit on the contrast ratio of 76.0 ppm (7.60 × 10−5) when including broadening, and 24.0 ppm (2.40 × 10−5) without. These upper limits rule out radius and albedo combinations of previously claimed detections. Conclusions. Broadening can significantly impact the ability of HRCCS to extract reflected light spectra and it must be considered when determining the contrast ratio, radius, and albedo of the planet. Asynchronous systems (Prot,⋆≠Porb) are most affected, including most hot Jupiters as well as Earth-size planets in the traditional habitable zones of some M-dwarfs.

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Section: Adaptations For Reflection Hrccsmentioning

confidence: 99%

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Spring

Birkby

Pino

et al. 2022

A&A

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“…Published low resolution studies of hot Jupiter atmospheres have reported tentative evidence for subsolar H 2 O abundances (Barstow et al 2017;Pinhas et al 2019;Welbanks et al 2019). This result was recently confirmed by high resolution spectroscopy of several planets, which show that subsolar H 2 O is often accompanied with supersolar CO abundances (Giacobbe et al 2021 Boucher et al 2021). Consequently, the measured C/O ratios of these planetary atmospheres are very high (0.85 − 1).…”

Section: The Origin Of Water-poor Hot Jupitersmentioning

confidence: 80%

Breaking Degeneracies in Formation Histories by Measuring Refractory Content in Gas Giants

Chachan,

Knutson,

Lothringer

et al. 2022

Preprint

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Relating planet formation to atmospheric composition has been a long-standing goal of the planetary science community. So far, most modeling studies have focused on predicting the enrichment of heavy elements and the C/O ratio in giant planet atmospheres. Although this framework provides useful constraints on the potential formation locations of gas giant exoplanets, carbon and oxygen measurements alone are not enough to determine where a given gas giant planet originated. Here, we show that characterizing the abundances of refractory elements (e.g., silicon, iron) can break these degeneracies. Refractory elements are present in the solid phase throughout most of the disk and their atmospheric abundances therefore reflect the solid-to-gas accretion ratio during formation. We introduce a new framework that parameterizes the atmospheric abundances of gas giant exoplanets in the form of three ratios: Si/H, O/Si, and C/Si. Si/H traces the solid-to-gas accretion ratio of a planet and is loosely equivalent to earlier notions of 'metallicity'. For O/Si and C/Si, we present a global picture of their variation with distance and time based on what we know from the solar system meteorites and an updated understanding of the variations of thermal processing within protoplanetary disks. We show that ultrahot Jupiters are ideal targets for atmospheric characterization studies using this framework, as we can measure the abundances of refractories, oxygen and carbon in the gas phase. Finally, we propose that hot Jupiters with silicate clouds and low water abundances might have accreted their envelopes between the soot line and the water snowline.

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“…Brogi et al (2018) presented the first detection of CO+H 2 O with TNG/GIANO, while Alonso-Floriano et al (2019) found water in the J and Y bands of CAHA/CARMENES. In 2021, CHFT/SPIRou also presented detections of H 2 O (Boucher et al 2021) and CO (Pelletier et al 2021). In the meantime, Giacobbe et al (2021) presented the si- Notes.…”

Section: Introductionmentioning

confidence: 98%

Detecting H₂O with CRIRES+: WASP-20b

Maimone

Brogi

Чиавасса

et al. 2022

A&A

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Context. Infrared spectroscopy over a wide spectral range and at the highest resolving powers (R>70 000) has proved to be one of the leading technique to unveil the atmospheric composition of dozens of exoplanets. The recently upgraded spectrograph CRIRES instrument at the VLT (CRIRES+) was operative for a first Science Verification in September 2021 and its new capabilities in atmospheric characterisation were ready to be tested. Aims. We analysed transmission spectra of the Hot Saturn WASP-20b in the K-band (1981-2394 nm) acquired with CRIRES+, aiming to detect the signature of H 2 O and CO. Methods. We used Principal Component Analysis to remove the dominant time-dependent contaminating sources such as telluric bands and the stellar spectrum and we extracted the planet spectrum by cross-correlating observations with 1D and 3D synthetic spectra, with no circulation included. Results. We present the tentative detection of molecular absorption from water-vapour at S/N equal to 4.2 and 4.7 by using only-H 2 O 1D and 3D models, respectively. The peak of the CCF occurred at the same rest-frame velocity for both model types (V rest =−1 ± 1 km s −1 ), and at the same projected planet orbital velocity but with different error bands (1D model: K P =131 +18 −29 km s −1 ; 3D: K P =131 +23 −39 km s −1 ). Our results are in agreement with the one expected in literature (132.9 ± 2.7 km s −1 ).Conclusions. Although sub-optimal observational conditions and issues with pipeline in calibrating and reducing our raw data set, we obtained the first tentative detection of water in the atmosphere of WASP-20b. We suggest a deeper analysis and additional observations to confirm our results and unveil the presence of CO.

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Characterizing Exoplanetary Atmospheres at High Resolution with SPIRou: Detection of Water on HD 189733 b

Cited by 35 publications

References 101 publications

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Breaking Degeneracies in Formation Histories by Measuring Refractory Content in Gas Giants

Detecting H₂O with CRIRES+: WASP-20b

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Characterizing Exoplanetary Atmospheres at High Resolution with SPIRou: Detection of Water on HD 189733 b

Cited by 35 publications

References 101 publications

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Breaking Degeneracies in Formation Histories by Measuring Refractory Content in Gas Giants

Detecting H2O with CRIRES+: WASP-20b

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Detecting H₂O with CRIRES+: WASP-20b