Collapse of Rotating Gas Clouds and Formation of Protostellar Disks: Effects of Temperature Change during Collapse

Saigo, Kazuya; Matsumoto, Toshiro; Hanawa, Tomoyuki

doi:10.1086/308493

Cited by 19 publications

(22 citation statements)

References 43 publications

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“…Fragmentation does not occur in the isothermal phase when the cloud collapses in a self-similar fashion because the self-similar solution with ¼ 1 exists even in a rotating collapsing cloud ( Matsumoto et al 1997;Matsumoto & Hanawa 1999). On the other hand, the clouds with > 1 form rotating disks and stop the contraction because no self-similar solution exists (Saigo et al 2000). These clouds can fragment as shown in Saigo et al (2004).…”

Section: Scales and Epochs Of Fragmentationmentioning

confidence: 99%

Formation Scenario for Wide and Close Binary Systems

Machida¹,

Tomisaka²,

Matsumoto³

et al. 2008

ApJ

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Fragmentation and binary formation processes are studied using three-dimensional resistive MHD nested grid simulations. Starting with a Bonnor-Ebert isothermal cloud rotating in a uniform magnetic field, we calculate the cloud evolution from the molecular cloud core (n=10^4 cm^-3) to the stellar core (n \simeq 10^22 cm^-3). We calculated 147 models with different initial magnetic, rotational, and thermal energies, and the amplitudes of the non-axisymmetric perturbation. In a collapsing cloud, fragmentation is mainly controlled by the initial ratio of the rotational to the magnetic energy, regardless of the initial thermal energy and amplitude of the non-axisymmetric perturbation. When the clouds have large rotational energies in relation to magnetic energies, fragmentation occurs in the low-density evolution phase (10^12 cm^-3 < n < 10^15 cm^-3) with separations of 3-300 AU. Fragments that appeared in this phase are expected to evolve into wide binary systems. On the other hand, fragmentation does not occur in the low-density evolution phase, when initial clouds have large magnetic energies in relation to the rotational energies. In these clouds, fragmentation only occurs in the high-density evolution phase (n > 10^17 cm^-3) after the clouds experience significant reduction of the magnetic field owing to Ohmic dissipation in the period of 10^12 cm^-3 < n < 10^15 cm^-3. Fragments appearing in this phase have separations of < 0.3 AU, and are expected to evolve into close binary systems. As a result, we found two typical fragmentation epochs, which cause different stellar separations. Although these typical separations are disturbed in the subsequent gas accretion phase, we might be able to observe two peaks of binary separations in extremely young stellar groups.Comment: 45 pages,12 figures, Submitted to ApJ, For high resolution figures see http://www2.scphys.kyoto-u.ac.jp/~machidam/protostar/proto/main-astroph.pd

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Section: Scales and Epochs Of Fragmentationmentioning

confidence: 99%

Formation Scenario for Wide and Close Binary Systems

Machida¹,

Tomisaka²,

Matsumoto³

et al. 2008

ApJ

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130

154

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“…This power-law index is steeper than that of the spherically collapsing polytropic gas of r À2/(2À) ¼ r À2:22 ( ¼ 1:1; Suto & Silk 1988). In the case of > 1, the ratio of the centrifugal force to the pressure gradient force increases gradually during the runaway collapse phase (Saigo et al 2000). Such a rapid increase in the centrifugal force effectively makes the gas stiffer.…”

Section: Model A: Direct Stellar Core Formationmentioning

confidence: 99%

Evolution of First Cores in Rotating Molecular Cores

Saigo

Tomisaka

2006

ApJ

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We investigate the effect of rotation on the star formation process quantitatively using axisymmetric numerical calculations. An adiabatic hydrostatic object (the so-called first core) forms in a contracting cloud core, after the central region becomes optically thick and continues to contract, driven by mass accretion onto it. The structure of a rotating first core is characterized by its total angular momentum J core and mass M core , both of which increase by accretion with time. We find that the first core evolves with a constant J core /M 2 core . Evolutionary paths of first cores can be classified into two types. In a slowly rotating core with J core /M 2 core < 0:015G/( ffiffi ffi 2 p c iso ), where c iso and G represent the isothermal sound speed in the molecular cloud core and the gravitational constant, respectively, the core begins ''second collapse'' after the central density exceeds the H 2 dissociation density. This is the same evolution as a standard scenario for a spherically symmetric, nonrotating core. On the other hand, a core with J core /M 2 core > 0:015G/( ffiffi ffi 2 p c iso ) stops its contraction before the central density reaches the H 2 dissociation density and does not begin the second collapse. These rapidly rotating first cores suffer from nonaxisymmetric instabilities, such as formation of massive spiral arms, deformation into a bar, or fragmentation. Although the rotating first cores have small average luminosities of L core ¼ 0:003 0:03Ṁ core /10 À5 M yr À1 À Á L , assuming a constant mass accretion rateṀ core . Their lifetimes last several thousand years or more, which is much longer than those expected for nonrotating clouds ($1000 yr). We expect that at least several percent of prestellar cores contain first cores as very low luminosity objects. Furthermore, we find a core with 0:012G/( ffiffi ffi 2 p c iso ) < J core /M 2 core < 0:015G/( ffiffi ffi 2 p c iso ) may form close binary systems with initial separation of 0.02-0.1 AU after the second collapse phase.

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“…The formation of a rotationally sup-19 Ϫ3 n p 1.82 # 10 c ported disk is an important consequence for the binary formation. If the equation of state is perfectly isothermal (g p ), the runaway collapse of a rotating cloud continues to form 1 the central singularity without forming a rotationally supported disk (Saigo & Hanawa 1998;Saigo et al 2000). However, the present simulation shows that the runaway collapse stops before producing the central singularity in the case of .…”

Section: Resultsmentioning

confidence: 55%

The Formation of Population III Binaries

Saigo

Matsumoto

Umemura

2004

ApJ

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We explore the possibility for the formation of Population III binaries. The collapse of a rotating cylinder is simulated with a three-dimensional, high-resolution nested grid, assuming the thermal history of primordial gas. The simulations are done with dimensionless units, and the results are applicable to low-mass as well as massive systems by scaling with the initial density. We find that if the initial angular momentum is as small as $\beta \approx 0.1$, where $\beta$ is the ratio of centrifugal force to pressure force, then the runaway collapse of the cloud stops to form a rotationally-supported disk. After the accretion of the envelope, the disk undergoes a ring instability, eventually fragmenting into a binary. If the initial angular momentum is relatively large, a bar-type instability arises, resulting in the collapse into a single star through rapid angular momentum transfer. The present results show that a significant fraction of Pop III stars are expected to form in binary systems, even if they are quite massive or less massive. The cosmological implications of Population III binaries are briefly discussed.Comment: Astrophysical Journal Letter, in press. 10 pages, 2 color figures, (full paper with high-resolution figures available at http://yso.mtk.nao.ac.jp/~saigo/papers/saigo2004a/saigo2004.pdf

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Collapse of Rotating Gas Clouds and Formation of Protostellar Disks: Effects of Temperature Change during Collapse

Cited by 19 publications

References 43 publications

Formation Scenario for Wide and Close Binary Systems

Formation Scenario for Wide and Close Binary Systems

Evolution of First Cores in Rotating Molecular Cores

The Formation of Population III Binaries

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