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Main Authors: Schmidt, Tobias M., Reiners, Ansgar, Murphy, Michael T., Curto, Gaspare Lo, Martins, Carlos J. A. P., Huke, Philipp
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.18485
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_version_ 1866915258967261184
author Schmidt, Tobias M.
Reiners, Ansgar
Murphy, Michael T.
Curto, Gaspare Lo
Martins, Carlos J. A. P.
Huke, Philipp
author_facet Schmidt, Tobias M.
Reiners, Ansgar
Murphy, Michael T.
Curto, Gaspare Lo
Martins, Carlos J. A. P.
Huke, Philipp
contents High quality wavelength calibration is crucial for science cases like radial-velocity studies of exoplanets, the search for a possible variation of fundamental constants, and the redshift drift experiment. However, for state-of-the-art spectrographs it has become difficult to verify the wavelength calibration on sky, because no astrophysical source provides spectra with sufficiently stable or accurate wavelength information. We therefore propose to use iodine absorption cells to validate the wavelength calibration. Observing a bright and featureless star through the iodine cell emulates an astrophysical target with exactly known spectral features that can be analyzed like any other science target, allowing to verify the wavelength calibration derived from the internal calibration sources and to identify systematics in the data processing. As demonstration, we temporarily installed an I$_2$ absorption cell at ESPRESSO. Employing a full forward modeling approach of the I$_2$ spectrum, including the instrumental line-spread function, we demonstrate wavelength calibration accuracy at the level of a few m/s. We also show that wavelength measurements do depend on the geometry of the light-injection into the spectrograph fibers. This highlights the importance of probing exactly the same light path as science targets, something not possible with internal calibration sources alone. We also demonstrate excellent radial-velocity stability at the <20 cm/s level in a full end-to-end fashion, from sky to data product. Our study therefore showcases the great potential of absorption cells for the verification and long-term monitoring of the wavelength calibration as well as the unique insights they can provide.
format Preprint
id arxiv_https___arxiv_org_abs_2504_18485
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Validation of the ESPRESSO Wavelength Calibration Using Iodine Absorption Cell Spectra
Schmidt, Tobias M.
Reiners, Ansgar
Murphy, Michael T.
Curto, Gaspare Lo
Martins, Carlos J. A. P.
Huke, Philipp
Instrumentation and Methods for Astrophysics
Cosmology and Nongalactic Astrophysics
Earth and Planetary Astrophysics
High quality wavelength calibration is crucial for science cases like radial-velocity studies of exoplanets, the search for a possible variation of fundamental constants, and the redshift drift experiment. However, for state-of-the-art spectrographs it has become difficult to verify the wavelength calibration on sky, because no astrophysical source provides spectra with sufficiently stable or accurate wavelength information. We therefore propose to use iodine absorption cells to validate the wavelength calibration. Observing a bright and featureless star through the iodine cell emulates an astrophysical target with exactly known spectral features that can be analyzed like any other science target, allowing to verify the wavelength calibration derived from the internal calibration sources and to identify systematics in the data processing. As demonstration, we temporarily installed an I$_2$ absorption cell at ESPRESSO. Employing a full forward modeling approach of the I$_2$ spectrum, including the instrumental line-spread function, we demonstrate wavelength calibration accuracy at the level of a few m/s. We also show that wavelength measurements do depend on the geometry of the light-injection into the spectrograph fibers. This highlights the importance of probing exactly the same light path as science targets, something not possible with internal calibration sources alone. We also demonstrate excellent radial-velocity stability at the <20 cm/s level in a full end-to-end fashion, from sky to data product. Our study therefore showcases the great potential of absorption cells for the verification and long-term monitoring of the wavelength calibration as well as the unique insights they can provide.
title Validation of the ESPRESSO Wavelength Calibration Using Iodine Absorption Cell Spectra
topic Instrumentation and Methods for Astrophysics
Cosmology and Nongalactic Astrophysics
Earth and Planetary Astrophysics
url https://arxiv.org/abs/2504.18485