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Main Authors: Gomez-Ramirez, F., Klapp, J., Cervantes-Cota, Jorge L., Arreaga-Garcia, G., Bahena, D.
Format: Preprint
Published: 2011
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Online Access:https://arxiv.org/abs/1103.0752
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author Gomez-Ramirez, F.
Klapp, J.
Cervantes-Cota, Jorge L.
Arreaga-Garcia, G.
Bahena, D.
author_facet Gomez-Ramirez, F.
Klapp, J.
Cervantes-Cota, Jorge L.
Arreaga-Garcia, G.
Bahena, D.
contents We examine the problem of the collapse and fragmentation of molecular clouds with a Gaussian density distribution with high resolution, double precision numerical simulations using the GADGET-2 code. To describe the thermodynamic properties of the cloud during the collapse -to mimic the rise of temperature predicted by radiative transfer- we use a barotropic equation of state that introduces a critical density to separate the isothermal and adiabatic regimes. We discuss the effects of this critical density in the formation of multiple systems. We confirm the tendency found for Plummer and Gaussian models that if the collapse changes from isothermal to adiabatic at earlier times that occurs for the models with a lower critical density, the collapse is slowed down, and this enhances the fragments' change to survive. However, this effect happens up to a threshold density below which single systems tend to form. On the other hand, by setting a bigger initial perturbation amplitude, the collapse is faster and in some cases a final single object is formed.
format Preprint
id arxiv_https___arxiv_org_abs_1103_0752
institution arXiv
publishDate 2011
record_format arxiv
spellingShingle Collapse and fragmentation of Gaussian barotropic protostellar clouds
Gomez-Ramirez, F.
Klapp, J.
Cervantes-Cota, Jorge L.
Arreaga-Garcia, G.
Bahena, D.
Solar and Stellar Astrophysics
We examine the problem of the collapse and fragmentation of molecular clouds with a Gaussian density distribution with high resolution, double precision numerical simulations using the GADGET-2 code. To describe the thermodynamic properties of the cloud during the collapse -to mimic the rise of temperature predicted by radiative transfer- we use a barotropic equation of state that introduces a critical density to separate the isothermal and adiabatic regimes. We discuss the effects of this critical density in the formation of multiple systems. We confirm the tendency found for Plummer and Gaussian models that if the collapse changes from isothermal to adiabatic at earlier times that occurs for the models with a lower critical density, the collapse is slowed down, and this enhances the fragments' change to survive. However, this effect happens up to a threshold density below which single systems tend to form. On the other hand, by setting a bigger initial perturbation amplitude, the collapse is faster and in some cases a final single object is formed.
title Collapse and fragmentation of Gaussian barotropic protostellar clouds
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/1103.0752