Star Formation Efficiency per Free-fall Time in nearby Galaxies

ABSTRACT The processes that regulate star formation within molecular clouds are still not well understood. Various star formation scaling relations have been proposed as an explanation, one of which is to formulate a relation between the star formation rate surface density $\rm \Sigma _{SFR}$ and the underlying gas surface density $\rm \Sigma _{gas}$. In this work, we test various star formation scaling relations, such as the Kennicutt–Schmidt relation, the volumetric star formation relation, the orbital time model, the crossing time model and the multi free-fall time-scale model, towards the North American Nebula and Pelican Nebula and in the cold clumps associated with them. Measuring stellar mass from young stellar objects and gaseous mass from CO measurements, we estimate the mean $\rm \Sigma _{SFR}$, the star formation rate per free-fall time and the star formation efficiency for clumps to be 1.5 $\rm M_{\odot}\, yr^{-1}\, kpc^{-2}$, 0.009 and 2.0 per cent, respectively, while for the whole region covered by both nebulae (which we call the ‘NAN’ complex) the values are 0.6 $\rm M_{\odot}\, yr^{-1}\, kpc^{-2}$, 0.0003 and 1.6 per cent, respectively. For the clumps, we notice that the observed properties are in line with the correlation obtained between $\rm \Sigma _{SFR}$ and $\rm \Sigma _{gas}$, and between $\rm \Sigma _{SFR}$ and $\rm \Sigma _{gas}$ per free-fall time and orbital time for Galactic clouds. At the same time, we do not observe any correlation with $\rm \Sigma _{gas}$ per crossing time and multi free-fall time. Even though we see correlations in the former cases, however, all models agree with each other within a factor of 0.5 dex. It is not possible to discriminate between these models because of the current uncertainties in the input observables. We also test the variation of $\rm \Sigma _{SFR}$ with the dense gas but, because of low statistics, a weak correlation is seen in our analysis.

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Physical properties and scaling relations of molecular clouds: the impact of star formation

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa3524 ◽

2020 ◽

Vol 500 (3) ◽

pp. 3552-3568

Author(s):

Kearn Grisdale

Keyword(s):

Star Formation ◽

Molecular Clouds ◽

Milky Way ◽

Free Fall ◽

Scaling Relations ◽

Formation Method ◽

Hydrodynamical Simulations ◽

Formation Efficiency ◽

The Impact ◽

Very High

ABSTRACT Using hydrodynamical simulations of a Milky Way-like galaxy, reaching 4.6 pc resolution, we study how the choice of star formation criteria impacts both galactic and giant molecular cloud (GMC) scales. We find that using a turbulent, self-gravitating star formation criteria leads to an increase in the fraction of gas with densities between 10 and $10^{4}{\, \rm {cm^{-3}}}$ when compared with a simulation using a molecular star formation method, despite both having nearly identical gaseous and stellar morphologies. Furthermore, we find that the site of star formation is effected with the the former tending to only produce stars in regions of very high density (${\gt}10^{4}{\, \rm {cm^{-3}}}$) gas, while the latter forms stars along the entire length of its spiral arms. The properties of GMCs are impacted by the choice of star formation criteria with the former method producing larger clouds. Despite the differences, we find that the relationships between clouds properties, such as the Larson relations, remain unaffected. Finally, the scatter in the measured star formation efficiency per free-fall time of GMCs remains present with both methods and is thus set by other factors.

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Is this an early stage merger? A case study on molecular gas and star formation properties of Arp 240

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa1826 ◽

2020 ◽

Vol 496 (4) ◽

pp. 5243-5261 ◽

Cited By ~ 1

Author(s):

Hao He ◽

C D Wilson ◽

Kazimierz Sliwa ◽

Daisuke Iono ◽

Toshiki Saito

Keyword(s):

Star Formation ◽

Early Stage ◽

Formation Rate ◽

Free Fall ◽

Radio Continuum ◽

Local Thermal Equilibrium ◽

Continuum Emission ◽

Molecular Gas ◽

Fall Time ◽

Very Large Array

ABSTRACT We present new high-resolution 12CO J = 1–0, J = 2–1, and 13CO J = 1–0 maps of the early stage merger Arp 240 (NGC 5257/8) obtained with the Atacama Large Millimeter/submillimeter Array (ALMA). Simulations in the literature suggest that the merger has just completed its first passage; however, we find that this system has a lower global gas fraction but a higher star formation efficiency (SFE) compared to typical close galaxy pairs, which suggests that this system may already be in an advanced merger stage. We combine the ALMA data with 12CO J = 3–2 observations from the Submillimeter Array and carry out RADEX modelling on several different regions. Both, the RADEX modelling and a local thermal equilibrium (LTE) analysis show that the regions are most likely to have a CO-to-H2 conversion factor αCO close to or perhaps even smaller than the typical value for (ultra)luminous infrared galaxies. Using 33-GHz data from the Very Large Array to measure the star formation rate, we find that most star-forming regions have molecular gas depletion times of less than 100 Myr. We calculated the SFE per free-fall time for different regions and find some regions appear to have values greater than 100 per cent. We find these regions generally show evidence for young massive clusters (YMCs). After exploring various factors, we argue that this is mainly due to the fact that radio continuum emission in those regions is dominated by that from YMCs, which results in an overestimate of the SFE per free-fall time.

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Kiso Hα Imaging Observations of Nearby Galaxies

Publications of the Astronomical Society of Australia ◽

10.1071/as98149 ◽

1998 ◽

Vol 15 (1) ◽

pp. 149-151

Author(s):

T. Hasegawa ◽

S. Sakamoto ◽

S. Nishiura ◽

Y. Ohyama ◽

Y. Sofue

Keyword(s):

Star Formation ◽

Compact Group ◽

Spiral Galaxy ◽

Clear Correlation ◽

Nuclear Region ◽

Diffuse Emission ◽

Schmidt Telescope ◽

Group System ◽

Nearby Galaxies ◽

Formation Efficiency

AbstractWe report Hα imaging observations of nearby galaxies with the Kiso Schmidt telescope. For spiral galaxy NGC 628, we found no clear correlation between Hα and CO intensities, and we discuss the star formation efficiency of this galaxy. No nuclear Hα emission in this galaxy was detected. This is consistent with spectroscopic observations which indicate that the nuclear region is in the post starburst phase. We also describe the Hα image of Hickson's compact group 92 in which diffuse emission is detected extending within the group system.

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The ALMaQUEST Survey – II. What drives central starbursts at z ∼ 0?

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa001 ◽

2020 ◽

Vol 492 (4) ◽

pp. 6027-6041 ◽

Cited By ~ 6

Author(s):

Sara L Ellison ◽

Mallory D Thorp ◽

Hsi-An Pan ◽

Lihwai Lin ◽

Jillian M Scudder ◽

...

Keyword(s):

Star Formation ◽

Surface Density ◽

Stellar Mass ◽

Starburst Galaxies ◽

Molecular Gas ◽

Central Regions ◽

Primary Driver ◽

Nearby Galaxies ◽

Field Unit ◽

Formation Efficiency

ABSTRACT Starburst galaxies have elevated star formation rates (SFRs) for their stellar mass. In Ellison et al., we used integral field unit maps of SFR surface density (ΣSFR) and stellar mass surface density (Σ⋆) to show that starburst galaxies in the local universe are driven by SFRs that are preferentially boosted in their central regions. Here, we present molecular gas maps obtained with the Atacama Large Millimeter Array (ALMA) observatory for 12 central starburst galaxies at z ∼ 0 drawn from the Mapping Nearby Galaxies at Apache Point Observatory (MaNGA) survey. The ALMA and MaNGA data are well matched in spatial resolution, such that the ALMA maps of molecular gas surface density ($\Sigma _{\rm H_2}$) can be directly compared with MaNGA maps at kpc-scale resolution. The combination of $\Sigma _{\rm H_2}$, Σ⋆ and ΣSFR at the same resolution allow us to investigate whether central starbursts are driven primarily by enhancements in star formation efficiency (SFE) or by increased gas fractions. By computing offsets from the resolved Kennicutt-Schmidt relation ($\Sigma _{\rm H_2}$ versus ΣSFR) and the molecular gas main sequence (Σ⋆ versus $\Sigma _{\rm H_2}$), we conclude that the primary driver of the central starburst is an elevated SFE. We also show that the enhancement in ΣSFR is accompanied by a dilution in O/H, consistent with a triggering that is induced by metal poor gas inflow. These observational signatures are found in both undisturbed (9/12 galaxies in our sample) and recently merged galaxies, indicating that both interactions and secular mechanisms contribute to central starbursts.

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DYNAMO: An upclose view of turbulent, clumpy galaxies

Proceedings of the International Astronomical Union ◽

10.1017/s1743921320001301 ◽

2019 ◽

Vol 15 (S352) ◽

pp. 317-317

Author(s):

Deanne Fisher

Keyword(s):

Star Formation ◽

Main Sequence ◽

Velocity Dispersion ◽

Molecular Gas ◽

Rotating Disks ◽

Giant Star ◽

Star Forming ◽

Nearby Galaxies ◽

Formation Efficiency ◽

The Universe

AbstractOver 2/3 of all star formation in the Universe occurs in gas-rich, super-high pressure clumpy galaxies in the epoch of redshift z ∼ 1 – 3. However, because these galaxies are so distant we are limited in the information available to study the properties of star formation and gas in these systems. I will present results using a sample of extremely rare, nearby galaxies (called DYNAMO) that are very well matched in gas fraction (fgas ∼ 20 – 80%), kinematics (rotating disks with velocity dispersions ranging 20 – 100 km/s), structure (exponential disks) and morphology (clumpy star formation) to high-z main-sequence galaxies. We therefore use DYNAMO galaxies as laboratories to study the processes inside galaxies in the dominate mode of star formation in the Universe. In this talk I will report on results from our programs with HST, ALMA, Keck, and NOEMA for DYNAMO galaxies that are aimed at testing models of star formation. We have discovered of an inverse relationship between gas velocity dispersion and molecular gas depletion time. This correlation is directly predicted by theories of feedback-regulated star formation; conversely, predictions of models in which turbulence is driven by gravity only are not consistent with our data. I will also show that feedback-regulated star formation can explain the redshift evolution of galaxy star formation efficiency. I will also present results from a recently acquired map of CO(2-1) in a clumpy galaxy with resolution less than 200 pc. With maps such as these we can begin to study these super giant star forming clumps at scales that are more comparable to local surveys. I will show results for the star formation efficiency of clumps, the boundedness of clumps of molecular gas, and discuss links between star formation efficiency and formation of clumps of stellar mass. The details of clumpy systems are a direct constraint of the results of simulations, especially on the nature of feedback in the high density environments of star formation that dominate the early Universe.

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THE STAR FORMATION EFFICIENCY IN NEARBY GALAXIES: MEASURING WHERE GAS FORMS STARS EFFECTIVELY

The Astronomical Journal ◽

10.1088/0004-6256/136/6/2782 ◽

2008 ◽

Vol 136 (6) ◽

pp. 2782-2845 ◽

Cited By ~ 1125

Author(s):

Adam K. Leroy ◽

Fabian Walter ◽

Elias Brinks ◽

Frank Bigiel ◽

W. J. G. de Blok ◽

...

Keyword(s):

Star Formation ◽

Nearby Galaxies ◽

Formation Efficiency

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Reconstructing three-dimensional densities from two-dimensional observations of molecular gas

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab356 ◽

2021 ◽

Vol 502 (4) ◽

pp. 5997-6009

Author(s):

Zipeng Hu ◽

Mark R Krumholz ◽

Christoph Federrath ◽

Riwaj Pokhrel ◽

Robert A Gutermuth

Keyword(s):

Star Formation ◽

Recent Observation ◽

Three Dimensional ◽

Free Fall ◽

Volume Density ◽

Mean Value ◽

Two Dimensional ◽

Density Estimates ◽

Fall Time ◽

Dimensional Measurements

ABSTRACT Star formation has long been known to be an inefficient process, in the sense that only a small fraction ϵff of the mass of any given gas cloud is converted to stars per cloud free-fall time. However, developing a successful theory of star formation will require measurements of both the mean value of ϵff and its scatter from one molecular cloud to another. Because ϵff is measured relative to the free-fall time, such measurements require accurate determinations of cloud volume densities. Efforts to measure the volume density from two-dimensional projected data, however, have thus far relied on treating molecular clouds as simple uniform spheres, while their real shapes are likely to be filamentary and their density distributions far from uniform. The resulting uncertainty in the true volume density is likely to be one of the major sources of error in observational estimates of ϵff. In this paper, we use a suite of simulations of turbulent, magnetized, radiative, self-gravitating star-forming clouds in order to examine whether it is possible to obtain more accurate volume density estimates and thereby reduce this error. We create mock observations from the simulations, and show that current analysis methods relying on the spherical assumption likely yield ∼0.26 dex underestimations and ∼0.51 dex errors in volume density estimates, corresponding to a ∼0.13 dex overestimation and a ∼0.25 dex scatter in ϵff, comparable to the scatter in observed cloud samples. We build a predictive model that uses information accessible in two-dimensional measurements – most significantly, the Gini coefficient of the surface density distribution – to produce estimates of the volume density with ∼0.3 dex less scatter. We test our method on a recent observation of the Ophiuchus cloud, and show that it successfully reduces the ϵff scatter.

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Star formation laws in extreme starbursts

Proceedings of the International Astronomical Union ◽

10.1017/s1743921313001518 ◽

2012 ◽

Vol 8 (S292) ◽

pp. 319-322

Author(s):

S. García-Burillo ◽

A. Usero ◽

A. Alonso-Herrero

Keyword(s):

Star Formation ◽

Star Formation Rate ◽

Formation Rate ◽

Free Fall ◽

Quality Data ◽

Molecular Gas ◽

Physical Processes ◽

High Quality Data ◽

Normal Galaxies ◽

Formation Efficiency

AbstractThe observational study of star formation laws is paramount to disentangling the physical processes at work on local and global scales in galaxies. To this aim we have expanded the sample of extreme starbursts, represented by local LIRGs and ULIRGs, with high-quality data obtained in the 1-0 line of HCN. The analysis of the new data shows that the star formation efficiency of the dense molecular gas, derived from the FIR/HCN luminosity ratio, is a factor 3-4 higher in extreme starbursts compared to normal galaxies. We find a duality in the Kennicutt-Schmidt laws that is enhanced if we account for the different conversion factor for HCN (αHCN) in extreme starbursts and correct for the unobscured star formation rate in normal galaxies. We find that it is possible to fit the observed differences in the FIR/HCN ratios between normal galaxies and LIRGs/ULIRGs with a common constant star formation rate per free-fall time (SFRff) if we assume that HCN densities are ∼1–2 orders of magnitude higher in LIRGs/ULIRGs, and provided that SFRff∼0.005-0.01 and/or if αHCN is a factor of a few lower than our favored values.

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