Evolution of First Cores in Rotating Molecular Cores

Saigo, Kazuya; Tomisaka, Kohji

doi:10.1086/504028

Cited by 81 publications

(106 citation statements)

References 44 publications

(92 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…With a 70 μm flux of ∼200 mJy (Belloche et al 2006), this correlation implies that Cha-MMS1 has a very low internal luminosity of ∼0.015 L . Luminosities ranging between 10 −4 and 0.1 L have been theoretically predicted at the stage of the first core, depending on the collapse model and the amount of rotation (Saigo & Tomisaka 2006;Omukai 2007). The faint luminosity of Cha-MMS1 looks therefore consistent with the luminosity of a first core.…”

Section: Evolutionary State Of Cha-mms1 and Cha-mms2mentioning

confidence: 64%

The end of star formation in Chamaeleon I?

Беллоче

Schüller

Parise

et al. 2011

A&A

144

View full text Add to dashboard Cite

Context. Chamaeleon I is the most active region in terms of star formation in the Chamaeleon molecular cloud complex. Although it is one of the nearest low-mass star forming regions, its population of prestellar and protostellar cores is not known and a controversy exists concerning its history of star formation. Aims. Our goal is to search for prestellar and protostellar cores and characterize the earliest stages of star formation in this cloud. Methods. We used the bolometer array LABOCA at the APEX telescope to map the cloud in dust continuum emission at 870 μm with a high sensitivity. This deep, unbiased survey was performed based on an extinction map derived from 2MASS data. The 870 μm map is compared with the extinction map and C 18 O observations, and decomposed with a multiresolution algorithm. The extracted sources are analysed by carefully taking into account the spatial filtering inherent in the data reduction process. A search for associations with young stellar objects is performed using Spitzer data and the SIMBAD database. Results. Most of the detected 870 μm emission is distributed in five filaments. We identify 59 starless cores, one candidate first hydrostatic core, and 21 sources associated with more evolved young stellar objects. The estimated 90% completeness limit of our survey is 0.22 M for the starless cores. The latter are only found above a visual extinction threshold of 5 mag. They are less dense than those detected in other nearby molecular clouds by a factor of a few on average, maybe because of the better sensitivity of our survey. The core mass distribution is consistent with the IMF at the high-mass end but is overpopulated at the low-mass end. In addition, at most 17% of the cores have a mass larger than the critical Bonnor-Ebert mass. Both results suggest that a large fraction of the starless cores may not be prestellar in nature. Based on the census of prestellar cores, Class 0 protostars, and more evolved young stellar objects, we conclude that the star formation rate has decreased with time in this cloud. Conclusions. The low fraction of candidate prestellar cores among the population of starless cores, the small number of Class 0 protostars, the high global star formation efficiency, the decrease of the star formation rate with time, and the low mass per unit length of the detected filaments all suggest that we may be witnessing the end of the star formation process in Chamaeleon I.

show abstract

Section: Evolutionary State Of Cha-mms1 and Cha-mms2mentioning

confidence: 64%

The end of star formation in Chamaeleon I?

Беллоче

Schüller

Parise

et al. 2011

A&A

144

View full text Add to dashboard Cite

show abstract

“…Nevertheless, none of these sources can be unambiguously characterized as true FHSCs partly because the theoretically-predicted parameter space of first cores is wide-spread; mass, lifetime, internal luminosity 1 and radius of 0.01 − 0.1 M ⊙ , 500-5×10 4 yr, 10 −4 − 0.1 L ⊙ , and 5-100 AU, respectively (Boss & Yorke 1995;Masunaga et al 1998;Omukai 2007;Commerçon et al 2012;Saigo & Tomisaka 2006;Saigo et al 2008;Tomida et al 2010). In addition, observations have not strongly constrained properties such as the rotation and mass accretion rate in the early phases of star formation.…”

Section: Introductionmentioning

confidence: 99%

ALMA Observations of SMM11 Reveal an Extremely Young Protostar in Serpens Main Cluster

Aso¹,

Ohashi²,

Aikawa³

et al. 2017

ApJL

Self Cite

View full text Add to dashboard Cite

We report the discovery of an extremely young protostar, SMM11, located in the associated submillimeter condensation in the Serpens Main cluster using the Atacama Large Millimeter/submillimeter Array (ALMA) during its Cycle 3 at 1.3 mm and an angular resolution of ∼ 0.′′ 5 ∼ 210 AU. SMM11 is a Class 0 protostar without any counterpart at 70 µm or shorter wavelengths. The ALMA observations show 1.3 mm continuum emission associated with a collimated 12 CO bipolar outflow. Spitzer and Herschel data show that SMM11 is extremely cold (T bol =26 K) and faint (L bol 0.9L ⊙ ). We estimate the inclination angle of the outflow to be ∼ 80 • , almost parallel to the plane of the sky, from simple fitting using wind-driven-shell model. The continuum visibilities consist of Gaussian and power-law components, suggesting a spherical envelope with a radius of ∼ 600 AU around the protostar. The estimated low C 18 O abundance, X(C 18 O)=1.5-3×10 −10 , is also consistent with its youth. The high outflow velocity, a few 10 km s −1 at a few 1000 AU, is much higher than theoretical simulations of first hydrostatic cores and we suggest that SMM11 is a transitional object right after the second collapse of the first core.

show abstract

“…Note that the first core lifetime is roughly determined by t fc = M fc /(Ṁ fc ), where M fc andṀ fc are the mass of the first core and the mass accretion rate onto the first core, and the first core becomes massive with rotation (Saigo & Tomisaka 2006). Thus, assuming a constant mass accretion rate, the rotating first core has a longer lifetime than the non-rotating first core.…”

Section: Cloud Collapse Before Protostar Formationmentioning

confidence: 99%

“…Therefore, magnetic braking is alleviated in the first core and the first core remnant evolves into a rotationally supported disc following protostar formation (Bate 1998(Bate , 2010Walch et al 2009;Machida & Matsumoto 2011c;Walch et al 2012). In addition, the low-velocity outflow is driven by the outer edge of the rotating first core where the magnetic field is coupled with neutral gas ( On the other hand, the lifetime of the first core is as short as t ∼ < 100 yr when the angular momentum of the first core is sufficiently small (Masunaga & Inutsuka 2000;Saigo & Tomisaka 2006;Saigo et al 2008). In such a case, there is not enough time for dissipation of the magnetic field, and the magnetic field continues to be amplified without dissipation (Machida et al 2007).…”

Section: Cloud Collapse Before Protostar Formationmentioning

confidence: 99%

“…Note that the first core is partly supported by the centrifugal force in magnetically supercritical models (Saigo & Tomisaka 2006;Saigo et al 2008). Since the dissipation of the magnetic field mainly occurs inside the first core, the magnetic field might become weaker in calculations that consider the heating by magnetic dissipation than in those that consider a barotropic equation of state due to the long lifetime of the first core.…”

Section: A Heating By Magnetic Dissipationmentioning

confidence: 99%

See 1 more Smart Citation

Different modes of star formation: gravitational collapse of magnetically subcritical cloud

Machida

Higuchi

Okuzumi

2017

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

Star formation in magnetically subcritical clouds is investigated using a threedimensional non-ideal magneto-hydrodynamics simulation. Since rapid cloud collapse is suppressed until the magnetic flux is sufficiently removed from the initially magnetically subcritical cloud by ambipolar diffusion, it takes ∼ > 5-10 t ff to form a protostar, where t ff is the freefall timescale of the initial cloud. The angular momentum of the star forming cloud is efficiently transferred to the interstellar medium before the rapid collapse begins, and the collapsing cloud has a very low angular momentum. Unlike the magnetically supercritical case, no large-scale low-velocity outflow appears in such a collapsing cloud due to the short lifetime of the first core. Following protostar formation, a very weak highvelocity jet, which has a small momentum and might disappear at a later time, is driven near the protostar, while the circumstellar disc does not grow during the early mass accretion phase. The results show that the star formation process in magnetically subcritical clouds is qualitatively different from that in magnetically supercritical clouds.

show abstract

Evolution of First Cores in Rotating Molecular Cores

Cited by 81 publications

References 44 publications

The end of star formation in Chamaeleon I?

The end of star formation in Chamaeleon I?

ALMA Observations of SMM11 Reveal an Extremely Young Protostar in Serpens Main Cluster

Different modes of star formation: gravitational collapse of magnetically subcritical cloud

Contact Info

Product

Resources

About