The Molecular Outflow in NGC 253 at a Resolution of Two Parsecs

Krieger, Nico; Bolatto, Alberto D.; Walter, Fabian; Leroy, Adam K.; Zschaechner, Laura K.; Meier, David S.; Ott, J.; Weiß, A.; Mills, Elisabeth A. C.; Levy, Rebecca C.; Veilleux, Sylvain; Gorski, Mark

doi:10.3847/1538-4357/ab2d9c

Cited by 66 publications

(105 citation statements)

References 66 publications

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“…A bi-conical wind emerges out of this region, apparent in Xrays (Strickland et al 2000(Strickland et al , 2002, Hα emission and other ionized lines (Sharp and Bland-Hawthorn 2010;Westmoquette et al 2011), neutral sodium emission (Heckman et al 2000), polycyclic aromatic hydrocarbon emission (Tacconi-Garman et al 2005), OH absorption (Turner 1985;Sturm et al 2011), and spatially resolved molecular emission (Fig. 1e; Bolatto et al 2013a;Walter et al 2017;Zschaechner et al 2018;Krieger et al 2019). The geometry of the wind is well characterized through Hα observations, emerging approximately perpendicular to the plane of the galaxy and almost in the plane of the sky (inclination of 12 • ) with an opening angle of ∼ 60 • .…”

Section: Ngc 253mentioning

confidence: 94%

“…The molecular outflow in NGC 253 has a CO-emitting mass of ∼ 3-4 × 10 7 M , and molecular mass loss rates estimated to be ∼ 20 M year −1 (Zschaechner et al 2018;Krieger et al 2019). By comparison, the mass of the Hα-emitting phase is 10 7 M (Westmoquette et al 2011), and the inferred mass loss rate is ∼ 4 M year −1 (Krieger et al 2019). The mass-loss rate in the hot, X-ray emitting fluid is estimated to be < 2.2 M year −1 for reasonable flow parameters (Strickland et al 2000).…”

Section: Ngc 253mentioning

confidence: 99%

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Cool outflows in galaxies and their implications

Veilleux

Maiolino

Bolatto

et al. 2020

Astron Astrophys Rev

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395

310

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Neutral-atomic and molecular outflows are a common occurrence in galaxies, near and far. They operate over the full extent of their galaxy hosts, from the innermost regions of galactic nuclei to the outermost reaches of galaxy halos. They carry a substantial amount of material that would otherwise have been used to form new stars. These cool outflows may have a profound impact on the evolution of their host galaxies and environments. This article provides an overview of the basic physics of cool outflows, a comprehensive assessment of the observational techniques and diagnostic tools used to characterize them, a detailed description of the best-studied cases, and a more general discussion of the statistical properties of these outflows in the local and distant universe. The remaining outstanding issues that have not yet been resolved are summarized at the end of the review to inspire new research directions.

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Section: Ngc 253mentioning

confidence: 94%

Section: Ngc 253mentioning

confidence: 99%

Cool outflows in galaxies and their implications

Veilleux

Maiolino

Bolatto

et al. 2020

Astron Astrophys Rev

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395

310

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“…In this section, we present our procedure to systematically identify central molecular outflows in a large sample of galaxies with similar properties. Rather than case studies tailored to individual galaxies (e.g., NGC 0253; Krieger et al 2019), we present a generic approach to identify galaxies which are likely to possess molecular outflows. This allows us to statistically compare properties of outflows (e.g., frequency, outflow masses, and outflow rates) as well as the non-detection rate of the sample in a robust, quantitative way.…”

Section: Methodsmentioning

confidence: 99%

“…Galactic outflows are known to consist of multiple gas phases: hot X-ray gas (e.g., Komossa et al 2003), warm ionized gas ([O iii], Hα; Venturi et al 2018;López-Cobá et al 2020;Hogarth et al 2021), neutral atomic gas (e.g., the Na i doublet; Sato et al 2009), warm and cold molecular gas (OH, CO; Feruglio et al 2010;Veilleux et al 2013;Zschaechner et al 2018;Lutz et al 2020), and dense molecular gas (HCN, HCO + ; Michiyama et al 2018;Krieger et al 2019). The molecular gas phase may dominate the outflow mass in certain active galaxies as revealed by multiphase observations of nearby galaxies, such as NGC 0253 (Krieger et al 2019), quasar hosts at redshift z ∼ 2.4 (Carniani et al 2015) or AGN hosts when comparing the molecular to their ionized gas phase (Fluetsch et al 2019). This motivates a detailed characterization of the molecular phase of outflows.…”

Section: Introductionmentioning

confidence: 99%

Frequency and nature of central molecular outflows in nearby star-forming disk galaxies

Stuber

Saito

Schinnerer

et al. 2021

A&A

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Central molecular outflows in spiral galaxies are assumed to modulate their host galaxy’s star formation rate (SFR) by removing gas from the inner region of the galaxy. Outflows consisting of different gas phases appear to be a common feature in local galaxies, yet, little is known about the frequency of molecular outflows in main sequence galaxies in the nearby universe. We develop a rigorous set of selection criteria, which allow the reliable identification of outflows in large samples of galaxies. Our criteria make use of central spectra, position-velocity diagrams and velocity-integrated intensity maps (line-wing maps). We use this method on high-angular resolution CO (2–1) observations from the PHANGS-ALMA survey, which provides observations of the molecular gas for a homogeneous sample of 90 nearby main sequence galaxies at a resolution of ∼100 pc. We find correlations between the assigned outflow confidence and stellar mass or global SFR. We determine the frequency of central molecular outflows to be 25 ± 2% considering all outflow candidates, or 20 ± 2% for secure outflows only. Our resulting outflow candidate sample of 16−20 galaxies shows an overall enhanced fraction of active galactic nuclei (AGN) (50%) and bars (89%) compared to the full sample (galaxies with AGN: 24%, with bar: 61%). We extend the trend between mass outflow rates and SFR known for high outflow rates down to lower values (log10 Ṁout [M⊙ yr−1] < 0). Mass loading factors are of order unity, indicating that these outflows are not efficient in quenching the SFR in main sequence galaxies.

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“…As star formation is highly localised in both space and time, the resulting feedback will be much more efficient at driving galactic-scale nuclear outflows (e.g. the outflow currently being driven in NGC 253, Krieger et al 2019;Zschaechner et al 2018) than the same star formation integrated over the whole duty cycle.…”

Section: Resolution Of the Conundrum: Time Variability In The Sfr Not Broken Star Formation Theoriesmentioning

confidence: 99%

The centres of M83 and the Milky Way: opposite extremes of a common star formation cycle

Callanan

Longmore

Kruijssen

et al. 2021

Monthly Notices of the Royal Astronomical Society

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In the centres of the Milky Way and M83, the global environmental properties thought to control star formation are very similar. However, M83’s nuclear star formation rate (SFR), as estimated by synchrotron and Hα emission, is an order of magnitude higher than the Milky Way’s. To understand the origin of this difference we use ALMA observations of HCN (1 − 0) and HCO+ (1 − 0) to trace the dense gas at the size scale of individual molecular clouds (0.54″, 12pc) in the inner ∼500 pc of M83, and compare this to gas clouds at similar resolution and galactocentric radius in the Milky Way. We find that both the overall gas distribution and the properties of individual clouds are very similar in the two galaxies, and that a common mechanism may be responsible for instigating star formation in both circumnuclear rings. Given the considerable similarity in gas properties, the most likely explanation for the order of magnitude difference in SFR is time variability, with the Central Molecular Zone (CMZ) currently being at a more quiescent phase of its star formation cycle. We show M83’s SFR must have been an order of magnitude higher 5 − 7 Myr ago. M83’s ‘starburst’ phase was highly localised, both spatially and temporally, greatly increasing the feedback efficiency and ability to drive galactic-scale outflows. This highly dynamic nature of star formation and feedback cycles in galaxy centres means (i) modeling and interpreting observations must avoid averaging over large spatial areas or timescales, and (ii) understanding the multi-scale processes controlling these cycles requires comparing snapshots of a statistical sample of galaxies in different evolutionary stages.

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The Molecular Outflow in NGC 253 at a Resolution of Two Parsecs

Cited by 66 publications

References 66 publications

Cool outflows in galaxies and their implications

Cool outflows in galaxies and their implications

Frequency and nature of central molecular outflows in nearby star-forming disk galaxies

The centres of M83 and the Milky Way: opposite extremes of a common star formation cycle

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