Lawson, Kellen and Schlieder, Joshua E. and Leisenring, Jarron M. and Bogat, Ell and Beichman, Charles A. and Bryden, Geoffrey and Gáspár, András and Groff, Tyler D. and McElwain, Michael W. and Meyer, Michael R. and Barclay, Thomas and Calissendorff, Per and De Furio, Matthew and Ygouf, Marie and Boccaletti, Anthony and Greene, Thomas P. and Krist, John and Plavchan, Peter and Rieke, Marcia J. and Roellig, Thomas L. and Stansberry, John and Wisniewski, John P. and Young, Erick T. (2023) JWST/NIRCam Coronagraphy of the Young Planet-hosting Debris Disk AU Microscopii. The Astronomical Journal, 166 (4). p. 150. ISSN 0004-6256
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Abstract
High-contrast imaging of debris disk systems permits us to assess the composition and size distribution of circumstellar dust, to probe recent dynamical histories, and to directly detect and characterize embedded exoplanets. Observations of these systems in the infrared beyond 2–3 μm promise access to both extremely favorable planet contrasts and numerous scattered-light spectral features—but have typically been inhibited by the brightness of the sky at these wavelengths. We present coronagraphy of the AU Microscopii (AU Mic) system using JWST's Near Infrared Camera (NIRCam) in two filters spanning 3–5 μm. These data provide the first images of the system's famous debris disk at these wavelengths and permit additional constraints on its properties and morphology. Conducting a deep search for companions in these data, we do not identify any compelling candidates. However, with sensitivity sufficient to recover planets as small as ∼0.1 Jupiter masses beyond ∼2'' (∼20 au) with 5σ confidence, these data place significant constraints on any massive companions that might still remain at large separations and provide additional context for the compact, multiplanet system orbiting very close-in. The observations presented here highlight NIRCam's unique capabilities for probing similar disks in this largely unexplored wavelength range, and they provide the deepest direct imaging constraints on wide-orbit giant planets in this very well-studied benchmark system.
Item Type: | Article |
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Subjects: | Eurolib Press > Physics and Astronomy |
Depositing User: | Managing Editor |
Date Deposited: | 10 Nov 2023 04:58 |
Last Modified: | 10 Nov 2023 04:58 |
URI: | http://info.submit4journal.com/id/eprint/3006 |