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Main Authors: Flaherty, Kevin, Knowlton, Peter, Smith-Gandy, Tasan, Hughes, A. Meredith, Kounkel, Marina, Jensen, Eric, Muzerolle, James, Covey, Kevin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.09823
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author Flaherty, Kevin
Knowlton, Peter
Smith-Gandy, Tasan
Hughes, A. Meredith
Kounkel, Marina
Jensen, Eric
Muzerolle, James
Covey, Kevin
author_facet Flaherty, Kevin
Knowlton, Peter
Smith-Gandy, Tasan
Hughes, A. Meredith
Kounkel, Marina
Jensen, Eric
Muzerolle, James
Covey, Kevin
contents Binary systems are a common site of planet formation, despite the destructive effects of the binary on the disk. While surveys of planet forming material have found diminished disk masses around medium separation ($\sim$10--100 au) binaries, less is known about tight ($<$10 au) binaries, where a significant circumbinary disk may escape the disruptive dynamical effects of the binary. We survey over 100 spectroscopic binaries in the Orion A region with ALMA, detecting significant continuum emission among 21 of them with disk masses ranging from 1--100 M$_{\oplus}$. We find evidence of systematically lower disk masses among the binary sample when compared to single star surveys, which may reflect a diminished planet forming potential around tight binaries. The infrared excess fraction among the binary sample is comparable to single stars, although the tight binaries without significant ALMA emission display tentative evidence of weaker 3-5$μ$m excesses. The depletion of cold dust is difficult to explain by clearing alone, and the role of additional mechanisms needs to be explored. It may be the result of the formation pathway for these objects, systematic differences in intrinsic properties (e.g., opacity) or a bias in how the sample was constructed.
format Preprint
id arxiv_https___arxiv_org_abs_2510_09823
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The influence of tight binaries on proto-planetary disk masses
Flaherty, Kevin
Knowlton, Peter
Smith-Gandy, Tasan
Hughes, A. Meredith
Kounkel, Marina
Jensen, Eric
Muzerolle, James
Covey, Kevin
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
Binary systems are a common site of planet formation, despite the destructive effects of the binary on the disk. While surveys of planet forming material have found diminished disk masses around medium separation ($\sim$10--100 au) binaries, less is known about tight ($<$10 au) binaries, where a significant circumbinary disk may escape the disruptive dynamical effects of the binary. We survey over 100 spectroscopic binaries in the Orion A region with ALMA, detecting significant continuum emission among 21 of them with disk masses ranging from 1--100 M$_{\oplus}$. We find evidence of systematically lower disk masses among the binary sample when compared to single star surveys, which may reflect a diminished planet forming potential around tight binaries. The infrared excess fraction among the binary sample is comparable to single stars, although the tight binaries without significant ALMA emission display tentative evidence of weaker 3-5$μ$m excesses. The depletion of cold dust is difficult to explain by clearing alone, and the role of additional mechanisms needs to be explored. It may be the result of the formation pathway for these objects, systematic differences in intrinsic properties (e.g., opacity) or a bias in how the sample was constructed.
title The influence of tight binaries on proto-planetary disk masses
topic Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2510.09823