Large-Scale Dissociation of Molecular Gas and Star Formation in M83

AbstractStudying the molecular phase of the interstellar medium in galaxies is fundamental for the understanding of the onset and evolution of star formation and the growth of supermassive black holes. We can use molecules as observational tools exploiting them as tracers of chemical, physical and dynamical conditions. In this short review, key molecules (e.g. HCN, HCO+, HNC, HC3N, CN, H3O+) in identifying the nature of buried activity and its evolution are discussed including some standard astrochemical scenarios. Furthermore, we can use IR excited molecular emission to probe the very inner regions of luminous infrared galaxies (LIRGs) allowing us to get past the optically thick dust barrier of the compact obscured nuclei, e.g. in the dusty LIRG NGC4418. High resolution studies are often necessary to separate effects of excitation and radiative transport from those of chemistry - one example is absorption and effects of stimulated emission in the ULIRG Arp220. Finally, molecular gas in large scale galactic outflows is briefly discussed.

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Large Scale Dissociation of Molecular Gas and Star Formation in M83

Star Forming Regions ◽

10.1007/978-94-009-4782-5_184 ◽

1987 ◽

pp. 628-628

Author(s):

R. J. Allen ◽

P. D. Atherton ◽

R. P. J. Tilanus

Keyword(s):

Star Formation ◽

Large Scale ◽

Molecular Gas

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Simulations of the star-forming molecular gas in an interacting M51-like galaxy

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz3600 ◽

2020 ◽

Vol 492 (2) ◽

pp. 2973-2995 ◽

Cited By ~ 11

Author(s):

Robin G Tress ◽

Rowan J Smith ◽

Mattia C Sormani ◽

Simon C O Glover ◽

Ralf S Klessen ◽

...

Keyword(s):

Star Formation ◽

Large Scale ◽

Formation Rate ◽

Three Dimensional ◽

Molecular Gas ◽

Secondary Importance ◽

Star Forming ◽

The Galaxy ◽

Cold Star ◽

Self Gravity

ABSTRACT We present here the first of a series of papers aimed at better understanding the evolution and properties of giant molecular clouds (GMCs) in a galactic context. We perform high-resolution, three-dimensional arepo simulations of an interacting galaxy inspired by the well-observed M51 galaxy. Our fiducial simulations include a non-equilibrium, time-dependent, chemical network that follows the evolution of atomic and molecular hydrogen as well as carbon and oxygen self-consistently. Our calculations also treat gas self-gravity and subsequent star formation (described by sink particles), and coupled supernova feedback. In the densest parts of the simulated interstellar medium (ISM), we reach sub-parsec resolution, granting us the ability to resolve individual GMCs and their formation and destruction self-consistently throughout the galaxy. In this initial work, we focus on the general properties of the ISM with a particular focus on the cold star-forming gas. We discuss the role of the interaction with the companion galaxy in generating cold molecular gas and controlling stellar birth. We find that while the interaction drives large-scale gas flows and induces spiral arms in the galaxy, it is of secondary importance in determining gas fractions in the different ISM phases and the overall star formation rate. The behaviour of the gas on small GMC scales instead is mostly controlled by the self-regulating property of the ISM driven by coupled feedback.

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Near-infrared observations of star formation and gas flows in the NUGA galaxy NGC 1365

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834255 ◽

2019 ◽

Vol 622 ◽

pp. A128 ◽

Cited By ~ 8

Author(s):

Nastaran Fazeli ◽

Gerold Busch ◽

Mónica Valencia-S. ◽

Andreas Eckart ◽

Michal Zajaček ◽

...

Keyword(s):

Star Formation ◽

Emission Line ◽

Galaxy Evolution ◽

Large Scale ◽

Near Infrared ◽

Molecular Gas ◽

Nuclear Region ◽

Stellar Kinematics ◽

Hydrogen Recombination ◽

Ngc 1365

In the framework of understanding the gas and stellar kinematics and their relations to AGNs and galaxy evolution scenarios, we present spatially resolved distributions and kinematics of the stars and gas in the central ∼800 pc radius of the nearby Seyfert galaxy NGC 1365. We obtained H + K- and K-band near-infrared (NIR) integral-field observations from VLT/SINFONI. Our results reveal strong broad and narrow emission-line components of ionized gas (hydrogen recombination lines Paα and Brγ) in the nuclear region, as well as hot dust with a temperature of ∼1300 K, both typical for type-1 AGNs. From MBH − σ* and the broad components of hydrogen recombination lines, we find a black-hole mass of (5 − 10)×106 M⊙. In the central ∼800 pc, we find a hot molecular gas mass of ∼615 M⊙, which corresponds to a cold molecular gas reservoir of (2 − 8)×108 M⊙. However, there is a molecular gas deficiency in the nuclear region. The gas and stellar-velocity maps both show rotation patterns consistent with the large-scale rotation of the galaxy. However, the gaseous and stellar kinematics show deviations from pure disk rotation, which suggest streaming motions in the central < 200 pc and a velocity twist at the location of the ring which indicates deviations in disk and ring rotation velocities in accordance with published CO kinematics. We detect a blueshifted emission line split in Paα, associated with the nuclear region only. We investigate the star-formation properties of the hot spots in the circumnuclear ring which have starburst ages of ≲10 Myr and find indications for an age gradient on the western side of the ring. In addition, our high-resolution data reveal further substructure within this ring which also shows enhanced star forming activity close to the nucleus.

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The EDGE-CALIFA survey: exploring the role of molecular gas on galaxy star formation quenching

Astronomy and Astrophysics ◽

10.1051/0004-6361/202039005 ◽

2020 ◽

Vol 644 ◽

pp. A97

Author(s):

D. Colombo ◽

S. F. Sanchez ◽

A. D. Bolatto ◽

V. Kalinova ◽

A. Weiß ◽

...

Keyword(s):

Star Formation ◽

Galaxy Evolution ◽

Large Scale ◽

Formation Rate ◽

Molecular Gas ◽

Star Forming ◽

Average Value ◽

First Results ◽

Gas Consumption ◽

Formation Efficiency

Understanding how galaxies cease to form stars represents an outstanding challenge for galaxy evolution theories. This process of “star formation quenching” has been related to various causes, including active galactic nuclei activity, the influence of large-scale dynamics, and the environment in which galaxies live. In this paper, we present the first results from a follow-up of CALIFA survey galaxies with observations of molecular gas obtained with the APEX telescope. Together with the EDGE-CARMA observations, we collected 12CO observations that cover approximately one effective radius in 472 CALIFA galaxies. We observe that the deficit of galaxy star formation with respect to the star formation main sequence (SFMS) increases with the absence of molecular gas and with a reduced efficiency of conversion of molecular gas into stars, which is in line with the results of other integrated studies. However, by dividing the sample into galaxies dominated by star formation and galaxies quenched in their centres (as indicated by the average value of the Hα equivalent width), we find that this deficit increases sharply once a certain level of gas consumption is reached, indicating that different mechanisms drive separation from the SFMS in star-forming and quenched galaxies. Our results indicate that differences in the amount of molecular gas at a fixed stellar mass are the primary drivers for the dispersion in the SFMS, and the most likely explanation for the start of star formation quenching. However, once a galaxy is quenched, changes in star formation efficiency drive how much a retired galaxy differs in its star formation rate from star-forming ones of similar masses. In other words, once a paucity of molecular gas has significantly reduced star formation, changes in the star formation efficiency are what drives a galaxy deeper into the red cloud, hence retiring it.

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The headlight cloud in NGC 628: An extreme giant molecular cloud in a typical galaxy disk

Astronomy and Astrophysics ◽

10.1051/0004-6361/201936060 ◽

2020 ◽

Vol 634 ◽

pp. A121 ◽

Cited By ~ 3

Author(s):

Cinthya N. Herrera ◽

Jérôme Pety ◽

Annie Hughes ◽

Sharon E. Meidt ◽

Kathryn Kreckel ◽

...

Keyword(s):

Star Formation ◽

High Resolution ◽

Molecular Cloud ◽

Molecular Clouds ◽

Large Scale ◽

Stellar Population ◽

High Mass ◽

Molecular Gas ◽

Giant Molecular Cloud ◽

The Impact

Context. Cloud-scale surveys of molecular gas reveal the link between giant molecular cloud properties and star formation across a range of galactic environments. Cloud populations in galaxy disks are considered to be representative of the normal star formation process, while galaxy centers tend to harbor denser gas that exhibits more extreme star formation. At high resolution, however, molecular clouds with exceptional gas properties and star formation activity may also be observed in normal disk environments. In this paper we study the brightest cloud traced in CO(2–1) emission in the disk of nearby spiral galaxy NGC 628. Aims. We characterize the properties of the molecular and ionized gas that is spatially coincident with an extremely bright H II region in the context of the NGC 628 galactic environment. We investigate how feedback and large-scale processes influence the properties of the molecular gas in this region. Methods. High-resolution ALMA observations of CO(2–1) and CO(1−0) emission were used to characterize the mass and dynamical state of the “headlight” molecular cloud. The characteristics of this cloud are compared to the typical properties of molecular clouds in NGC 628. A simple large velocity gradient (LVG) analysis incorporating additional ALMA observations of 13CO(1−0), HCO+(1−0), and HCN(1−0) emission was used to constrain the beam-diluted density and temperature of the molecular gas. We analyzed the MUSE spectrum using Starburst99 to characterize the young stellar population associated with the H II region. Results. The unusually bright headlight cloud is massive (1 − 2 × 107 M⊙), with a beam-diluted density of nH2 = 5 × 104 cm−3 based on LVG modeling. It has a low virial parameter, suggesting that the CO emission associated with this cloud may be overluminous due to heating by the H II region. A young (2 − 4 Myr) stellar population with mass 3 × 105 M⊙ is associated. Conclusions. We argue that the headlight cloud is currently being destroyed by feedback from young massive stars. Due to the large mass of the cloud, this phase of the its evolution is long enough for the impact of feedback on the excitation of the gas to be observed. The high mass of the headlight cloud may be related to its location at a spiral co-rotation radius, where gas experiences reduced galactic shear compared to other regions of the disk and receives a sustained inflow of gas that can promote the mass growth of the cloud.

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CO (J=2-1) Observations of the Molecular Cloud Complex in the Galactic Center

International Astronomical Union Colloquium ◽

10.1017/s0252921100019394 ◽

1994 ◽

Vol 140 ◽

pp. 168-169

Author(s):

Tomoharu Oka ◽

Tetsuo Hasegawa ◽

Masahiko Hayashi ◽

Toshihiro Handa ◽

Sei'ichi Sakamoto

Keyword(s):

Star Formation ◽

Molecular Cloud ◽

Molecular Clouds ◽

Large Scale ◽

Galactic Center ◽

Molecular Gas ◽

Star Forming ◽

Near Future ◽

Cloud Complex ◽

Mapping Observation

AbstractWe report a large scale mapping observation of the Galactic center region in the CO (J=2-1) line using the Tokyo-NRO 60cm survey telescope. Distribution of the CO (J=2-1) emission in the I-V plane suggests that molecular clouds forms a huge complex (Nuclear Molecular cloud Complex, NMC). Tracers of star formation activities in the last 106-108 years show that star formation has occured in a ring ~ 100 pc in radius. Relative to this Star Forming Ring, the molecular gas is distributed mainly on the positive longitude side. This may indicate that much of the gas in NMC is in transient orbit to fall into the star forming ring or to the nucleus in the near future.

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The molecular gas content in a protocluster at z = 17: Star formation and AGN feedback

Proceedings of the International Astronomical Union ◽

10.1017/s1743921319009475 ◽

2019 ◽

Vol 15 (S352) ◽

pp. 168-170

Author(s):

Q. D’Amato ◽

I. Prandoni ◽

R. Gilli ◽

M. Massardi ◽

E. Liuzzo ◽

...

Keyword(s):

Star Formation ◽

Large Scale ◽

Gas Content ◽

Molecular Gas ◽

Star Forming ◽

Physical Conditions ◽

Radio Jets ◽

Multi Wavelength ◽

Data Coverage

AbstractA large-scale structure has been recently discovered at z = 1.7, around a powerful FRII radio galaxy. Eight Star Forming Galaxies (SFGs) have been discovered within Δ z ≍ 0.0095 and at < 1 Mpc from the FRII, indicating that this is a signpost of a protocluster. Furthermore, a significant X-ray diffuse emission overlapping the Eastern lobe of the FRII has been detected. Protoclusters are the ideal targets to investigate the complex assembly processes leading to the formation of local galaxy clusters. We will exploit new ALMA CO(2-1) observations (PI: R. Gilli) of the entire region around the FRII galaxy to trace the molecular gas content, in order to discover new protocluster members. Coupling these measurements with the multi-wavelength data coverage available for this field, we aim at placing constrains on the physical conditions in which star formation occurs, and ultimately infer the role of the radio jets in triggering it.

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Molecular Gas in the Centers of Barred and Starburst Galaxies

International Astronomical Union Colloquium ◽

10.1017/s0252921100019813 ◽

1994 ◽

Vol 140 ◽

pp. 282-292

Author(s):

Jeffrey D. P. Kenney

Keyword(s):

Star Formation ◽

Large Scale ◽

Starburst Galaxy ◽

Molecular Gas ◽

Barred Galaxies ◽

Twin Peaks ◽

Ngc 1068 ◽

Lindblad Resonance ◽

Inner Lindblad Resonance ◽

Co Emission

AbstractHigh resolution interferometric CO maps of the circumnuclear regions of several barred galaxies show intense CO emission arising from twin peaks, which are oriented perpendicular to the large-scale stellar bars and located where dust lanes intersect nuclear rings of HII regions. These twin gas concentrations can be explained by the crowding of gas streamlines near stellar inner Lindblad resonances. In the barred nuclear starburst galaxy NGC 3504, a large concentration of molecular gas is centered on the nucleus, apparently inside an inner Lindblad resonance. Star formation is consuming the gas most rapidly where the rotation curve is nearly solid body, suggesting that tidal shear helps control the rate of star formation. A comparison with M82 and NGC 1068 suggests that the starburst in NGC 3504 is in an early phase of its evolution, and that starburst evolution is strongly influenced by shear.

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Centrally concentrated molecular gas driving galactic-scale ionized gas outflows in star-forming galaxies

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa3512 ◽

2020 ◽

Vol 500 (3) ◽

pp. 3802-3820

Author(s):

L M Hogarth ◽

A Saintonge ◽

L Cortese ◽

T A Davis ◽

S M Croom ◽

...

Keyword(s):

Star Formation ◽

Spatial Resolution ◽

Large Scale ◽

Formation Rate ◽

Control Sample ◽

Joint Analysis ◽

Molecular Gas ◽

Ionized Gas ◽

Data Set ◽

Star Forming

ABSTRACT We perform a joint analysis of high spatial resolution molecular gas and star-formation rate (SFR) maps in main-sequence star-forming galaxies experiencing galactic-scale outflows of ionized gas. Our aim is to understand the mechanism that determines which galaxies are able to launch these intense winds. We observed CO(1→0) at 1-arcsec resolution with ALMA in 16 edge-on galaxies, which also have 2-arcsec spatial-resolution optical integral field observations from the SAMI Galaxy Survey. Half the galaxies in the sample were previously identified as harbouring intense and large-scale outflows of ionized gas (‘outflow types’) and the rest serve as control galaxies. The data set is complemented by integrated CO(1→0) observations from the IRAM 30-m telescope to probe the total molecular gas reservoirs. We find that the galaxies powering outflows do not possess significantly different global gas fractions or star-formation efficiencies when compared with a control sample. However, the ALMA maps reveal that the molecular gas in the outflow-type galaxies is distributed more centrally than in the control galaxies. For our outflow-type objects, molecular gas and star-formation are largely confined within their inner effective radius (reff), whereas in the control sample, the distribution is more diffuse, extending far beyond reff. We infer that outflows in normal star-forming galaxies may be caused by dynamical mechanisms that drive molecular gas into their central regions, which can result in locally enhanced gas surface density and star-formation.

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