The theory of globulettes: candidate precursors of brown dwarfs and free-floating planets in H ii regions

Haworth, Thomas J.; Facchini, Stefano; Clarke, C. J.

doi:10.1093/mnras/stu2174

Cited by 35 publications

(11 citation statements)

References 29 publications

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“…The results obtained by microlensing surveys toward the Galactic Bulge suggest that the frequency of freefloating Jovian planets are 0.25 planets per main-sequence star (Mróz et al 2017). Several dynamical processes have been proposed in order to explain the origin of free-floating planets (FFPs) in our Galaxy: planet-planet scattering (Veras & Raymond 2012), direct formation in grobulettes (Gahm et al 2007;Haworth et al 2015), and the aftermath of evolved stars such as supernova explosions (Veras & Tout 2012).…”

Section: Occurrence Rate Of Free-floating Planetsmentioning

confidence: 99%

Survival Rates of Planets in Open Clusters: the Pleiades, Hyades, and Praesepe clusters

Fujii,

Hori

2018

Preprint

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Context. In clustered environments, stellar encounters can liberate planets from their host stars via close encounters. Although the detection probability of planets suggests that the planet population in open clusters resembles that in the field, only a few dozen planet-hosting stars have been discovered in open clusters. Aims. We explore the survival rates of planets against stellar encounters in open clusters similar to the Pleiades, Hyades, and Praesepe and embedded clusters. Methods. We performed a series of N-body simulations of high-density and low-density open clusters, open clusters that grow via mergers of subclusters, and embedded clusters. We semi-analytically calculated the survival rate of planets in star clusters up to ∼1 Gyr using relative velocities, masses, and impact parameters of intruding stars. Results. Less than 1.5 % of close-in planets within 1 AU and at most 7 % of planets with 1-10 AU are ejected by stellar encounters in clustered environments after the dynamical evolution of star clusters. If a planet population from 0.01-100 AU in an open cluster initially follows the probability distribution function of exoplanets with semi-major axis (a p ) between 0.03-3 AU in the field discovered by RV surveys (∝ a −0.6 p ), the PDF of surviving planets beyond ∼ 10 AU in open clusters can be slightly modified to ∝ a −0.76 p . The production rate of free-floating planets (FFPs) per star is 0.0096-0.18, where we have assumed that all the stars initially have one giant planet with a mass of 1-13 M Jup in a circular orbit. The expected frequency of FFPs is compatible with the upper limit on that of FFPs indicated by recent microlensing surveys. Our survival rates of planets in open clusters suggest that planets within 10 AU around FGKM-type stars are rich in relatively-young ( 10-100 Myr for open clusters and ∼1-10 Myr for embedded clusters), less massive open clusters, which are promising targets for planet searches.

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Section: Occurrence Rate Of Free-floating Planetsmentioning

confidence: 99%

Survival Rates of Planets in Open Clusters: the Pleiades, Hyades, and Praesepe clusters

Fujii,

Hori

2018

Preprint

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“…Haworth et al (2015) doubt the possibility that the external pressure in the form of radiation or ram pressure can drive globulettes to form brown dwarfs or free-floating planets, and instead they propose the collapse of the globulettes might be triggered by their collisions with the shells that border the expanding H II regions. If Proplyd133-353 was formed in such a globulette near θ 1 Ori C due to either mechanism, we might explain both its younger age (with respect to the one of the ONC) and the lifetime of its disk since its parental cloud can protect it from direct photoevaporation for a timescale of 10 5 -10 6 years (Gahm et al 2007;Haworth et al 2015).…”

Section: The Possible Nature Of Proplyd133-353mentioning

confidence: 99%

A Candidate Planetary-Mass Object With a Photoevaporating Disk in Orion

Fang

Kim

Pascucci

et al. 2016

ApJL

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In this work, we report the discovery of a candidate planetary-mass object with a photoevaporating protoplanetary disk, Proplyd133-353, which is near the massive star θ 1 Ori C at the center of the Orion Nebula Cluster (ONC). The object was known to have extended emission pointing away from θ 1 OriC, indicating ongoing external photoevaporation. Our near-infrared spectroscopic data and the location on the H-R diagram suggest that the central source of Proplyd133-353 is substellar (∼M9.5) and has a mass probably less than 13 Jupiter mass and an age younger than 0.5 Myr. Proplyd133-353 shows a similar ratio of X-ray luminosity to stellar luminosity to other young stars in the ONC with a similar stellar luminosity and has a similar proper motion to the mean one of confirmed ONC members. We propose that Proplyd133-353 formed in a very low-mass dusty cloud or an evaporating gas globule near θ 1 Ori C as a second generation of star formation, which can explain both its young age and the presence of its disk.

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“…While the model assumes equilibrium, it is unstable to collapse if sufficiently compressed. Haworth et al (2015) used pressure-bounded BE spheres to model the stability and evolution of small globulettes in Carina cataloged by Grenman & Gahm (2014), including the Tadpole. We revisit the parameters of the Tadpole assuming it is well described by a BE sphere but using the physical parameters we measure with the MUSE data.…”

Section: The Tadpole As a Pressure-boundedmentioning

confidence: 99%

“…If even a small fraction of these globulettes undergo gravitational collapse, they may contribute significantly to the low-mass end of the IMF. However, Haworth et al (2015) showed that these low-mass globulettes are stable and require an additional perturbation to stimulate collapse. Estimated photoevaporation rates (e.g., Smith et al 2004;Reiter et al 2015a) suggest that such small, low-mass objects will be rapidly ablated.…”

Section: Introductionmentioning

confidence: 99%

Illuminating the Tadpole's metamorphosis I: MUSE observations of a small globule in a sea of ionizing photons

Reiter,

McLeod,

Klaassen

et al. 2019

Preprint

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We present new MUSE/VLT observations of a small globule in the Carina H ii region that hosts the HH 900 jet+outflow system. Data were obtained with the GALACSI ground-layer adaptive optics system in wide-field mode, providing spatially-resolved maps of diagnostic emission lines. These allow us to measure the variation of the physical properties in the globule and jet+outflow system. We find high temperatures (T e ≈ 10 4 K), modest extinction (A V ≈ 2.5 mag), and modest electron densities (n e ≈ 200 cm −3 ) in the ionized gas. Higher excitation lines trace the ionized outflow; both the excitation and ionization in the outflow increase with distance from the opaque globule. In contrast, lower excitation lines that are collisionally de-excited at densities 10 4 cm −3 trace the highly collimated protostellar jet. Assuming the globule is an isothermal sphere confined by the pressure of the ionization front, we compute a Bonnor-Ebert mass of ∼ 3.7 M . This is two orders of magnitude higher than previous mass estimates, calling into question whether small globules like the Tadpole contribute to the bottom of the IMF. Derived globule properties are consistent with a cloud that has been and/or will be compressed by the ionization front on its surface. At the estimated globule photoevaporation rate of ∼ 5 × 10 −7 M yr −1 , the globule will be completely ablated in ∼ 7 Myr. Stars that form in globules like the Tadpole will emerge into the H ii later and may help resolve some of the temporal tension between disk survival and enrichment.

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The theory of globulettes: candidate precursors of brown dwarfs and free-floating planets in H ii regions

Cited by 35 publications

References 29 publications

Survival Rates of Planets in Open Clusters: the Pleiades, Hyades, and Praesepe clusters

Survival Rates of Planets in Open Clusters: the Pleiades, Hyades, and Praesepe clusters

A Candidate Planetary-Mass Object With a Photoevaporating Disk in Orion

Illuminating the Tadpole's metamorphosis I: MUSE observations of a small globule in a sea of ionizing photons

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