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Main Authors: Parker, Luke T., Birkby, Jayne L., Landman, Rico, Wardenier, Joost P., Young, Mitchell E., Vaughan, Sophia R., van Sluijs, Lennart, Brogi, Matteo, Parmentier, Vivien, Line, Michael R.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.08867
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author Parker, Luke T.
Birkby, Jayne L.
Landman, Rico
Wardenier, Joost P.
Young, Mitchell E.
Vaughan, Sophia R.
van Sluijs, Lennart
Brogi, Matteo
Parmentier, Vivien
Line, Michael R.
author_facet Parker, Luke T.
Birkby, Jayne L.
Landman, Rico
Wardenier, Joost P.
Young, Mitchell E.
Vaughan, Sophia R.
van Sluijs, Lennart
Brogi, Matteo
Parmentier, Vivien
Line, Michael R.
contents High-resolution cross-correlation spectroscopy (HRCCS) combined with adaptive optics has been enormously successful in advancing our knowledge of exoplanet atmospheres, from chemistry to rotation and atmospheric dynamics. This powerful technique now drives major science cases for ELT instrumentation including METIS/ELT, GMTNIRS/GMT and MICHI/TMT, targeting biosignatures on rocky planets at 3-5 $μ$m, but remains untested beyond 3.5 $μ$m where the sky thermal background begins to provide the dominant contribution to the noise. We present 3.51-5.21 $μ$m M-band CRIRES+/VLT observations of the archetypal young directly imaged gas giant $β$ Pictoris b, detecting CO absorption at S/N = 6.6 at 4.73 $μ$m and H$_2$O at S/N = 5.7, and thus extending the use of HRCCS into the thermal background noise dominated infrared. Using this novel spectral range to search for more diverse chemistry we report marginal evidence of SiO at S/N = 4.3, potentially indicative that previously proposed magnesium-silicate clouds in the atmosphere are either patchy, transparent at M-band wavelengths, or possibly absent on the planetary hemisphere observed. The molecular detections are rotationally broadened by the spin of $β$ Pic b, and we infer a planetary rotation velocity of $v$sin(i) = 22$\pm$2 km s$^{-1}$ from the cross-correlation with the H$_2$O model template, consistent with previous K-band studies. We discuss the observational challenges posed by the thermal background and telluric contamination in the M-band, the custom analysis procedures required to mitigate these issues, and the opportunities to exploit this new infrared window for HRCCS using existing and next-generation instrumentation.
format Preprint
id arxiv_https___arxiv_org_abs_2405_08867
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Into the red: an M-band study of the chemistry and rotation of $β$ Pictoris b at high spectral resolution
Parker, Luke T.
Birkby, Jayne L.
Landman, Rico
Wardenier, Joost P.
Young, Mitchell E.
Vaughan, Sophia R.
van Sluijs, Lennart
Brogi, Matteo
Parmentier, Vivien
Line, Michael R.
Earth and Planetary Astrophysics
Instrumentation and Methods for Astrophysics
High-resolution cross-correlation spectroscopy (HRCCS) combined with adaptive optics has been enormously successful in advancing our knowledge of exoplanet atmospheres, from chemistry to rotation and atmospheric dynamics. This powerful technique now drives major science cases for ELT instrumentation including METIS/ELT, GMTNIRS/GMT and MICHI/TMT, targeting biosignatures on rocky planets at 3-5 $μ$m, but remains untested beyond 3.5 $μ$m where the sky thermal background begins to provide the dominant contribution to the noise. We present 3.51-5.21 $μ$m M-band CRIRES+/VLT observations of the archetypal young directly imaged gas giant $β$ Pictoris b, detecting CO absorption at S/N = 6.6 at 4.73 $μ$m and H$_2$O at S/N = 5.7, and thus extending the use of HRCCS into the thermal background noise dominated infrared. Using this novel spectral range to search for more diverse chemistry we report marginal evidence of SiO at S/N = 4.3, potentially indicative that previously proposed magnesium-silicate clouds in the atmosphere are either patchy, transparent at M-band wavelengths, or possibly absent on the planetary hemisphere observed. The molecular detections are rotationally broadened by the spin of $β$ Pic b, and we infer a planetary rotation velocity of $v$sin(i) = 22$\pm$2 km s$^{-1}$ from the cross-correlation with the H$_2$O model template, consistent with previous K-band studies. We discuss the observational challenges posed by the thermal background and telluric contamination in the M-band, the custom analysis procedures required to mitigate these issues, and the opportunities to exploit this new infrared window for HRCCS using existing and next-generation instrumentation.
title Into the red: an M-band study of the chemistry and rotation of $β$ Pictoris b at high spectral resolution
topic Earth and Planetary Astrophysics
Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2405.08867