Observational Evidence for Rotational Desorption of Complex Molecules by Radiative Torques from Orion BN/KL

Observational Evidence for Rotational Desorption of Complex Molecules by Radiative Torques from Orion BN/KL

Abstract Complex organic molecules (COMs) are believed to form in the ice mantle of dust grains and are released to the gas by thermal sublimation when grain mantles are heated to temperatures of T d ≳ 100 K . However, some COMs are detected in regions with temperatures below 100 K. Recently, a new...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 908; no. 2; pp. 159 - 169
Main Authors: Tram, Le Ngoc, Lee, Hyeseung, Hoang, Thiem, Michail, Joseph M., Chuss, David T., Nickerson, Sarah, Rangwala, Naseem, Reach, William T.
Format: Journal Article
Language:English
Published: Philadelphia The American Astronomical Society 01-02-2021
IOP Publishing
American Astronomical Society
Subjects:
Astrochemistry
Astrophysics
Desorption
Disruption
Dust
Ice formation
Interstellar clouds
Interstellar dust
Interstellar dust extinction
Low temperature
Massive stars
Observational studies
Organic chemistry
Polarization
Sciences of the Universe
Star formation
Starlight polarization
Sublimation
Torque
Interstellar dust extinction
Starlight polarization
Astrochemistry
Interstellar clouds
Star formation
Interstellar dust
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Summary:Abstract Complex organic molecules (COMs) are believed to form in the ice mantle of dust grains and are released to the gas by thermal sublimation when grain mantles are heated to temperatures of T d ≳ 100 K . However, some COMs are detected in regions with temperatures below 100 K. Recently, a new mechanism of rotational desorption due to centrifugal stress induced by radiative torques (RATs) was proposed by Hoang & Tram (2020) that can desorb COMs at low temperatures. In this paper, we report observational evidence for rotational desorption of COMs toward the nearest massive star-forming region, Orion BN/KL. We compare the abundance of three representative COMs that have very high binding energy computed by the rotational desorption mechanism with observations by ALMA, and demonstrate that the rotational desorption mechanism can explain the existence of such COMs. We also analyze the polarization data from SOFIA/HAWC+ and JCMT/SCUBA-2 and find that the polarization degree at far-infrared/submillimeter decreases with increasing the grain temperature for T d ≳ 71 K . This is consistent with the theoretical prediction using the RAT alignment theory and Radiative Torque Disruption mechanism. Such an anticorrelation between dust polarization and dust temperature supports the rotational disruption as well as rotational desorption mechanism of COMs induced by RATs.
Bibliography:AAS26607
Interstellar Matter and the Local Universe
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/abccbe