Dr Thomas Williams

Low-J CO Line Ratios from Single-dish CO Mapping Surveys and PHANGS-ALMA

The Astrophysical Journal American Astronomical Society 927:2 (2022) 149-149

Authors:

AK Leroy, E Rosolowsky, A Usero, K Sandstrom, E Schinnerer, A Schruba, AD Bolatto, J Sun, AT Barnes, F Belfiore, F Bigiel, JS Den Brok, Y Cao, ID Chiang, M Chevance, DA Dale, C Eibensteiner, CM Faesi, SCO Glover, A Hughes, MJ Jiménez Donaire, RS Klessen, EW Koch, JMD Kruijssen, D Liu, SE Meidt, HA Pan, J Pety, J Puschnig, M Querejeta, T Saito, A Sardone, EJ Watkins, A Weiss, TG Williams

Abstract:

Star formation in galaxies is governed by the amount of molecular gas and the efficiency that gas is converted into stars. However, assessing the amount of molecular gas relies on the CO-to-H2 conversion factor (alpha_CO), which is known to vary with molecular gas conditions like density, temperature, and dynamical state -- the same conditions that also alter star formation efficiency. The variation of alpha_CO, particularly in galaxy centers where alpha_CO can drop by nearly an order of magnitude, thus causes major uncertainties in current molecular gas and star formation efficiency measurements. Using ALMA observations of multiple low-J 12CO, 13CO, and C18O lines in several barred galaxy centers, we found that alpha_CO is primarily driven by CO opacity changes and therefore shows strong correlations with observables like velocity dispersion and 12CO/13CO line ratio. Motivated by these results, we have constructed a new alpha_CO prescription which accounts for emissivity effects in galaxy centers and verified it on a set of barred and non-barred galaxies with measured alpha_CO values from dust. Applying our new prescription to 65 galaxies from the PHANGS-ALMA survey, we found an overall three times higher star formation efficiency in barred galaxy centers than in non-barred galaxy centers, and such a trend is obscured when using a constant alpha_CO or other existing prescriptions. Our results suggest that the high star formation rate observed in barred galaxy centers is due to an enhanced star formation efficiency compared to non-barred galaxy centers or the disk regions, rather than a substantially increased amount of molecular gas in barred galaxy centers

The Gas–Star Formation Cycle in Nearby Star-forming Galaxies. II. Resolved Distributions of CO and Hα Emission for 49 PHANGS Galaxies

The Astrophysical Journal American Astronomical Society 927:1 (2022) 9-9

Authors:

HA Pan, E Schinnerer, A Hughes, A Leroy, B Groves, AT Barnes, F Belfiore, F Bigiel, GA Blanc, Y Cao, M Chevance, E Congiu, DA Dale, C Eibensteiner, E Emsellem, CM Faesi, SCO Glover, K Grasha, CN Herrera, IT Ho, RS Klessen, JMD Kruijssen, P Lang, D Liu, R McElroy, SE Meidt, EJ Murphy, J Pety, M Querejeta, A Razza, E Rosolowsky, T Saito, F Santoro, A Schruba, J Sun, N Tomičić, A Usero, D Utomo, TG Williams

Abstract:

[[abstract]]The relative distribution of molecular gas and star formation in galaxies gives insight into the physical processes and timescales of the cycle between gas and stars. In this work, we track the relative spatial configuration of CO and Hα emission at high resolution in each of our galaxy targets and use these measurements to quantify the distributions of regions in different evolutionary stages of star formation: from molecular gas without star formation traced by Hα to star-forming gas, and to H ii regions. The large sample, drawn from the Physics at High Angular resolution in Nearby GalaxieS ALMA and narrowband Hα (PHANGS-ALMA and PHANGS-Hα) surveys, spans a wide range of stellar masses and morphological types, allowing us to investigate the dependencies of the gas‒star formation cycle on global galaxy properties. At a resolution of 150 pc, the incidence of regions in different stages shows a dependence on stellar mass and Hubble type of galaxies over the radial range probed. Massive and/or earlier-type galaxies in our sample exhibit a significant reservoir of molecular gas without star formation traced by Hα, while lower-mass galaxies harbor substantial H ii regions that may have dispersed their birth clouds or formed from low-mass, more isolated clouds. Galactic structures add a further layer of complexity to the relative distribution of CO and Hα emission. Trends between galaxy properties and distributions of gas traced by CO and Hα are visible only when the observed spatial scale is ≪500 pc, reflecting the critical resolution requirement to distinguish stages of the star formation process.[[notice]]補正完

The PHANGS-HST Survey: Physics at High Angular Resolution in Nearby Galaxies with the Hubble Space Telescope

The Astrophysical Journal: Supplement Series American Astronomical Society 258:1 (2022) 10-10

Authors:

JC Lee, BC Whitmore, DA Thilker, S Deger, KL Larson, L Ubeda, GS Anand, M Boquien, R Chandar, DA Dale, E Emsellem, AK Leroy, E Rosolowsky, E Schinnerer, J Schmidt, J Lilly, J Turner, S Van Dyk, RL White, AT Barnes, F Belfiore, F Bigiel, GA Blanc, Y Cao, M Chevance, E Congiu, OV Egorov, SCO Glover, K Grasha, B Groves, JD Henshaw, A Hughes, RS Klessen, E Koch, K Kreckel, JMD Kruijssen, D Liu, LA Lopez, N Mayker, SE Meidt, EJ Murphy, HA Pan, J Pety, M Querejeta, A Razza, T Saito, P Sánchez-Blázquez, F Santoro, A Sardone, F Scheuermann

Abstract:

Molecular gas is believed to be the fuel for star formation and nuclear activity in Seyfert galaxies. To explore the role of magnetic fields in funneling molecular gas into the nuclear region, measurements of the magnetic fields embedded in molecular gas are needed. By applying the new velocity gradient technique (VGT) to ALMA and PAWS's CO isotopolog data, we obtain the first detection of CO-associated magnetic fields in several nearby Seyfert galaxies and their unprecedented high-resolution magnetic field maps. The VGT-measured magnetic fields in molecular gas globally agree with those inferred from existing HAWC+ dust polarization and VLA synchrotron polarization. An overall good alignment between the magnetic fields traced by VGT-CO and by synchrotron polarization may support the correlation between star formation and cosmic ray generation. We find that the magnetic fields traced by VGT-CO have a significant radial component in the central regions of most Seyferts in our sample, where efficient molecular gas inflows or outflows may happen. In particular, we find local misalignment between the magnetic fields traced by CO and dust polarization within the nuclear ring of NGC 1097, and the former aligns with the central bar's orientation. This misalignment reveals different magnetic field configurations in different gas phases and may provide an observational diagnostic for the ongoing multi-phase fueling of Seyfert activity.Comment: 24 pages, 14 figure

Local Environments of Low-redshift Supernovae

Astrophysical Journal 923:1 (2021)

Authors:

SA Cronin, D Utomo, AK Leroy, EA Behrens, J Chastenet, T Holland-Ashford, EW Koch, LA Lopez, KM Sandstrom, TG Williams

Abstract:

We characterize the local (2 kpc sized) environments of Type Ia, II, and Ib/c supernovae (SNe) that have recently occurred in nearby (d ≲ 50 Mpc) galaxies. Using ultraviolet (UV; from Galaxy Evolution Explorer) and infrared (IR; from Wide-field Infrared Survey Explorer) maps of 359 galaxies and a sample of 472 SNe, we measure the star formation rate surface density (ΣSFR) and stellar mass surface density (Σ∗) in a 2 kpc beam centered on each SN site. We show that core-collapse SNe are preferentially located along the resolved galactic star-forming main sequence, whereas Type Ia SNe are extended to lower values of ΣSFR at fixed Σ∗, indicative of locations inside quiescent galaxies or quiescent regions of galaxies. We also test how well the radial distribution of each SN type matches the radial distributions of UV and IR light in each host galaxy. We find that, to first order, the distributions of all types of SNe mirror those of both near-IR light (3.4 and 4.5 μm, tracing the stellar mass distribution) and mid-IR light (12 and 22 μm, tracing emission from hot, small grains), and also resemble our best-estimate ΣSFR. All types of SNe appear more radially concentrated than the UV emission of their host galaxies. In more detail, the distributions of Type II SNe show small statistical differences from those of near-IR light. We attribute this overall structural uniformity to the fact that within any individual galaxy, ΣSFR and Σ∗ track one another well, with variations in ΣSFR/Σ∗ most visible when comparing between galaxies.

PHANGS-ALMA: Arcsecond CO(2-1) Imaging of Nearby Star-forming Galaxies

Astrophysical Journal Supplement Series 257:2 (2021)

Authors:

AK Leroy, E Schinnerer, A Hughes, E Rosolowsky, J Pety, A Schruba, A Usero, GA Blanc, M Chevance, E Emsellem, CM Faesi, CN Herrera, D Liu, SE Meidt, M Querejeta, T Saito, KM Sandstrom, J Sun, TG Williams, GS Anand, AT Barnes, EA Behrens, F Belfiore, SM Benincasa, I Bešlić, F Bigiel, AD Bolatto, JS Den Brok, Y Cao, R Chandar, J Chastenet, ID Chiang, E Congiu, DA Dale, S Deger, C Eibensteiner, OV Egorov, A García-Rodríguez, SCO Glover, K Grasha, JD Henshaw, IT Ho, AA Kepley, J Kim, RS Klessen, K Kreckel, EW Koch, JMD Kruijssen, KL Larson, JC Lee, LA Lopez, J Machado, N Mayker, R McElroy, EJ Murphy, EC Ostriker, HA Pan, I Pessa, J Puschnig, A Razza, P Sánchez-Blázquez, F Santoro, A Sardone, F Scheuermann, K Sliwa, MC Sormani, SK Stuber, DA Thilker, JA Turner, D Utomo, EJ Watkins, B Whitmore

Abstract:

We present PHANGS-ALMA, the first survey to map CO J = 2 → 1 line emission at ∼1″ ∼100 pc spatial resolution from a representative sample of 90 nearby (d ≲ 20 Mpc) galaxies that lie on or near the z = 0 "main sequence"of star-forming galaxies. CO line emission traces the bulk distribution of molecular gas, which is the cold, star-forming phase of the interstellar medium. At the resolution achieved by PHANGS-ALMA, each beam reaches the size of a typical individual giant molecular cloud, so that these data can be used to measure the demographics, life cycle, and physical state of molecular clouds across the population of galaxies where the majority of stars form at z = 0. This paper describes the scientific motivation and background for the survey, sample selection, global properties of the targets, Atacama Large Millimeter/submillimeter Array (ALMA) observations, and characteristics of the delivered data and derived data products. As the ALMA sample serves as the parent sample for parallel surveys with MUSE on the Very Large Telescope, the Hubble Space Telescope, AstroSat, the Very Large Array, and other facilities, we include a detailed discussion of the sample selection. We detail the estimation of galaxy mass, size, star formation rate, CO luminosity, and other properties, compare estimates using different systems and provide best-estimate integrated measurements for each target. We also report the design and execution of the ALMA observations, which combine a Cycle 5 Large Program, a series of smaller programs, and archival observations. Finally, we present the first 1″ resolution atlas of CO emission from nearby galaxies and describe the properties and contents of the first PHANGS-ALMA public data release.