Cloud Collision Signatures in the Central Molecular Zone
Molecular cloud collisions are a prominent theory for the formation of stars. Observational studies into cloud collisions identify the collision via a bridging feature: a continuous strip of line emission that connects two intensity peaks that are related in position space and separated in velocity...
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| Format: | Article |
| Language: | English |
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Maynooth Academic Publishing
2024-10-01
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| Series: | The Open Journal of Astrophysics |
| Online Access: | https://doi.org/10.33232/001c.124112 |
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| _version_ | 1846114125717962752 |
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| author | Rees A. Barnes Felix D. Priestley |
| author_facet | Rees A. Barnes Felix D. Priestley |
| author_sort | Rees A. Barnes |
| collection | DOAJ |
| description | Molecular cloud collisions are a prominent theory for the formation of stars. Observational studies into cloud collisions identify the collision via a bridging feature: a continuous strip of line emission that connects two intensity peaks that are related in position space and separated in velocity space. Currently, most observations of collisions and these bridging features take place in the Milky Way disc. They are also theorized to take place in the Central Molecular Zone (CMZ), where temperatures and densities are both significantly higher than in the disc. For studies in the Milky Way Disc, the most commonly-used tracer tends to be CO. However, for studies in the CMZ, where the density and temperature are significantly higher, low-J CO lines lose their ability to adequately highlight the bridging feature of cloud collisions. As a result, studies have begun using other tracers, whose physical and chemical behavior has not been studied under CMZ conditions. We perform combined hydrodynamical, chemical and radiative transfer simulations of cloud collisions under both disc- and CMZ-like conditions, and investigate collision signatures in a number of commonly-observed molecular lines. Under the Milky Way disc conditions CO has the standard bridging feature; however, the other tracers, CS, HCO+, N<sub>2</sub>H+ only emit in the intermediate-velocity bridge region, making the feature itself challenging to detect. In the CMZ, the higher density and temperature make the bridging feature far more indistinct for CO, but the other tracers have morphologically similar bridging features to the CO disc model, validating their use as tracers of cloud collisions under these conditions. |
| format | Article |
| id | doaj-art-f0353e1ea27545e4b36937c7a47a3ad7 |
| institution | Kabale University |
| issn | 2565-6120 |
| language | English |
| publishDate | 2024-10-01 |
| publisher | Maynooth Academic Publishing |
| record_format | Article |
| series | The Open Journal of Astrophysics |
| spelling | doaj-art-f0353e1ea27545e4b36937c7a47a3ad72024-12-20T20:04:47ZengMaynooth Academic PublishingThe Open Journal of Astrophysics2565-61202024-10-017Cloud Collision Signatures in the Central Molecular ZoneRees A. BarnesFelix D. PriestleyMolecular cloud collisions are a prominent theory for the formation of stars. Observational studies into cloud collisions identify the collision via a bridging feature: a continuous strip of line emission that connects two intensity peaks that are related in position space and separated in velocity space. Currently, most observations of collisions and these bridging features take place in the Milky Way disc. They are also theorized to take place in the Central Molecular Zone (CMZ), where temperatures and densities are both significantly higher than in the disc. For studies in the Milky Way Disc, the most commonly-used tracer tends to be CO. However, for studies in the CMZ, where the density and temperature are significantly higher, low-J CO lines lose their ability to adequately highlight the bridging feature of cloud collisions. As a result, studies have begun using other tracers, whose physical and chemical behavior has not been studied under CMZ conditions. We perform combined hydrodynamical, chemical and radiative transfer simulations of cloud collisions under both disc- and CMZ-like conditions, and investigate collision signatures in a number of commonly-observed molecular lines. Under the Milky Way disc conditions CO has the standard bridging feature; however, the other tracers, CS, HCO+, N<sub>2</sub>H+ only emit in the intermediate-velocity bridge region, making the feature itself challenging to detect. In the CMZ, the higher density and temperature make the bridging feature far more indistinct for CO, but the other tracers have morphologically similar bridging features to the CO disc model, validating their use as tracers of cloud collisions under these conditions.https://doi.org/10.33232/001c.124112 |
| spellingShingle | Rees A. Barnes Felix D. Priestley Cloud Collision Signatures in the Central Molecular Zone The Open Journal of Astrophysics |
| title | Cloud Collision Signatures in the Central Molecular Zone |
| title_full | Cloud Collision Signatures in the Central Molecular Zone |
| title_fullStr | Cloud Collision Signatures in the Central Molecular Zone |
| title_full_unstemmed | Cloud Collision Signatures in the Central Molecular Zone |
| title_short | Cloud Collision Signatures in the Central Molecular Zone |
| title_sort | cloud collision signatures in the central molecular zone |
| url | https://doi.org/10.33232/001c.124112 |
| work_keys_str_mv | AT reesabarnes cloudcollisionsignaturesinthecentralmolecularzone AT felixdpriestley cloudcollisionsignaturesinthecentralmolecularzone |