Dr Thomas Williams

The HASHTAG Project: the first submillimeter images of the Andromeda galaxy from the ground

Astrophysical Journal Supplement IOP Science 257 (2021) 52

Authors:

Martin Bureau, Dimitra Rigopoulou

Abstract:

Observing nearby galaxies with submillimeter telescopes on the ground has two major challenges. First, the brightness is significantly reduced at long submillimeter wavelengths compared to the brightness at the peak of the dust emission. Second, it is necessary to use a high-pass spatial filter to remove atmospheric noise on large angular scales, which has the unwelcome by-product of also removing the galaxy’s large-scale structure. We have developed a technique for producing high-resolution submillimeter images of galaxies of large angular size by using the telescope on the ground to determine the small-scale structure (the large Fourier components) and a space telescope (Herschel or Planck) to determine the large-scale structure (the small Fourier components). Using this technique, we are carrying out the HARP and SCUBA-2 High Resolution Terahertz Andromeda Galaxy Survey (HASHTAG), an international Large Program on the James Clerk Maxwell Telescope, with one aim being to produce the first high-fidelity high-resolution submillimeter images of Andromeda. In this paper, we describe the survey, the method we have developed for combining the space-based and ground-based data, and present the first HASHTAG images of Andromeda at 450 and 850 µm. We also have created a method to predict the CO(J=3–2) line flux across M 31, which contaminates the 850 µm band. We find that while normally the contamination is below our sensitivity limit, the contamination can be significant (up to 28%) in a few of the brightest regions of the 10 kpc ring. We therefore also provide images with the predicted line emission removed.

Dense molecular gas properties on 100 pc scales across the disc of NGC 3627

Monthly Notices of the Royal Astronomical Society 506:1 (2021) 963-988

Authors:

I Bešlić, AT Barnes, F Bigiel, J Puschnig, J Pety, C Herrera Contreras, AK Leroy, A Usero, E Schinnerer, SE Meidt, E Emsellem, A Hughes, C Faesi, K Kreckel, FMC Belfiore, M Chevance, JS Den Brok, C Eibensteiner, SCO Glover, K Grasha, MJ Jimenez-Donaire, RS Klessen, JMD Kruijssen, D Liu, I Pessa, M Querejeta, E Rosolowsky, T Saito, F Santoro, A Schruba, MC Sormani, TG Williams

Abstract:

It is still poorly constrained how the densest phase of the interstellar medium varies across galactic environment. A large observing time is required to recover significant emission from dense molecular gas at high spatial resolution, and to cover a large dynamic range of extragalactic disc environments. We present new NOrthern Extended Millimeter Array (NOEMA) observations of a range of high critical density molecular tracers (HCN, HNC, HCO+) and CO isotopologues (13CO, C18O) towards the nearby (11.3 Mpc) strongly barred galaxy NGC 3627. These observations represent the current highest angular resolution (1.85 arcsec; 100 pc) map of dense gas tracers across a disc of a nearby spiral galaxy, which we use here to assess the properties of the dense molecular gas, and their variation as a function of galactocentric radius, molecular gas, and star formation. We find that the HCN(1-0)/CO(2-1) integrated intensity ratio does not correlate with the amount of recent star formation. Instead, the HCN(1-0)/CO(2-1) ratio depends on the galactic environment, with differences between the galaxy centre, bar, and bar-end regions. The dense gas in the central 600 pc appears to produce stars less efficiently despite containing a higher fraction of dense molecular gas than the bar ends where the star formation is enhanced. In assessing the dynamics of the dense gas, we find the HCN(1-0) and HCO+(1-0) emission lines showing multiple components towards regions in the bar ends that correspond to previously identified features in CO emission. These features are cospatial with peaks of Hα emission, which highlights that the complex dynamics of this bar-end region could be linked to local enhancements in the star formation.

PHANGS-ALMA Data Processing and Pipeline

Astrophysical Journal Supplement Series 255:1 (2021)

Authors:

AK Leroy, A Hughes, D Liu, J Pety, E Rosolowsky, T Saito, E Schinnerer, A Schruba, A Usero, CM Faesi, CN Herrera, M Chevance, APS Hygate, AA Kepley, EW Koch, M Querejeta, K Sliwa, D Will, CD Wilson, GS Anand, A Barnes, F Belfiore, I Bešlić, F Bigiel, GA Blanc, AD Bolatto, M Boquien, Y Cao, R Chandar, J Chastenet, ID Chiang, E Congiu, DA Dale, S Deger, JS Den Brok, C Eibensteiner, E Emsellem, A García-Rodríguez, SCO Glover, K Grasha, B Groves, JD Henshaw, MJ Jiménez Donaire, J Kim, RS Klessen, K Kreckel, JMD Kruijssen, KL Larson, JC Lee, N Mayker, R McElroy, SE Meidt, A Mok, HA Pan, J Puschnig, A Razza, P Sánchez-Bl'Azquez, KM Sandstrom, F Santoro, A Sardone, F Scheuermann, J Sun, DA Thilker, JA Turner, L Ubeda, D Utomo, EJ Watkins, TG Williams

Abstract:

We describe the processing of the PHANGS-ALMA survey and present the PHANGS-ALMA pipeline, a public software package that processes calibrated interferometric and total power data into science-ready data products. PHANGS-ALMA is a large, high-resolution survey of CO(2-1) emission from nearby galaxies. The observations combine ALMA's main 12 m array, the 7 m array, and total power observations, and use mosaics of dozens to hundreds of individual pointings. We describe the processing of the u-v data, imaging and deconvolution, linear mosaicking, combining interferometer and total power data, noise estimation, masking, data product creation, and quality assurance. Our pipeline has a general design and can also be applied to Very Large Array and ALMA observations of other spectral lines and continuum emission. We highlight our recipe for deconvolution of complex spectral line observations, which combines multiscale clean, single-scale clean, and automatic mask generation in a way that appears robust and effective. We also emphasize our two-track approach to masking and data product creation. We construct one set of "broadly masked"data products, which have high completeness but significant contamination by noise, and another set of "strictly masked"data products, which have high confidence but exclude faint, low signal-to-noise emission. Our quality assurance tests, supported by simulations, demonstrate that 12 m+7 m deconvolved data recover a total flux that is significantly closer to the total power flux than the 7 m deconvolved data alone. In the appendices, we measure the stability of the ALMA total power calibration in PHANGS-ALMA and test the performance of popular short-spacing correction algorithms.

The organization of cloud-scale gas density structure: High-resolution co versus 3.6μm brightness contrasts in nearby galaxies

Astrophysical Journal 913:2 (2021)

Authors:

SE Meidt, AK Leroy, M Querejeta, E Schinnerer, J Sun, A Van der Wel, E Emsellem, J Henshaw, A Hughes, JM Diederik Kruijssen, E Rosolowsky, A Schruba, A Barnes, F Bigiel, GA Blanc, M Chevance, Y Cao, DA Dale, C Faesi, SCO Glover, K Grasha, B Groves, C Herrera, RS Klessen, K Kreckel, D Liu, HA Pan, J Pety, T Saito, A Usero, E Watkins, TG Williams

Abstract:

In this paper we examine the factors that shape the distribution of molecular gas surface densities on the 150 pc scale across 67 morphologically diverse star-forming galaxies in the PHANGS-ALMA CO (2-1) survey. Dividing each galaxy into radial bins, we measure molecular gas surface density contrasts, defined here as the ratio between a fixed high percentile of the CO distribution and a fixed reference level in each bin. This reference level captures the level of the faint CO floor that extends between bright filamentary features, while the intensity level of the higher percentile probes the structures visually associated with bright, dense interstellar medium features like spiral arms, bars, and filaments. We compare these contrasts to matched percentile-based measurements of the 3.6 μm emission measured using Spitzer/IRAC imaging, which trace the underlying stellar mass density. We find that the logarithms of CO contrasts on 150 pc scales are 3-4 times larger than, and positively correlated with, the logarithms of 3.6 μm contrasts probing smooth nonaxisymmetric stellar bar and spiral structures. The correlation appears steeper than linear, consistent with the compression of gas as it flows supersonically in response to large-scale stellar structures, even in the presence of weak or flocculent spiral arms. Stellar dynamical features appear to play an important role in setting the cloud-scale gas density in our galaxies, with gas self-gravity perhaps playing a weaker role in setting the 150 pc scale distribution of gas densities.

Benchmarking Dust Emission Models in M101

Astrophysical Journal 912:2 (2021)

Authors:

J Chastenet, K Sandstrom, ID Chiang, BS Hensley, BT Draine, KD Gordon, EW Koch, AK Leroy, D Utomo, TG Williams

Abstract:

We present a comparative study of four physical dust models and two single-temperature modified blackbody models by fitting them to the resolved WISE, Spitzer, and Herschel photometry of M101 (NGC 5457). Using identical data and a grid-based fitting technique, we compare the resulting dust and radiation field properties derived from the models. We find that the dust mass yielded by the different models can vary by up to a factor of 3 (factor of 1.4 between physical models only), although the fits have similar quality. Despite differences in their definition of the carriers of the mid-IR aromatic features, all physical models show the same spatial variations for the abundance of that grain population. Using the well-determined metallicity gradient in M101 and resolved gas maps, we calculate an approximate upper limit on the dust mass as a function of radius. All physical dust models are found to exceed this maximum estimate over some range of galactocentric radii. We show that renormalizing the models to match the same Milky Way high-latitude cirrus spectrum and abundance constraints can reduce the dust mass differences between models and bring the total dust mass below the maximum estimate at all radii.