Dr Thomas Williams

Star Clusters in the Near-ultraviolet-optical-near-infrared: Spectral Energy Distribution Modeling with Direct Markers of Gas and Dust Emission

The Astrophysical Journal American Astronomical Society 991:1 (2025) 76

Authors:

Kiana F Henny, Daniel A Dale, Rupali Chandar, Médéric Boquien, David A Thilker, Bradley C Whitmore, Janice C Lee, M Jimena Rodriguez, Daniel Maschmann, Aida Wofford, Rémy Indebetouw, Leonardo Úbeda, Brent Groves, Hamid Hassani, Kirsten L Larson, Thomas G Williams, Kathryn Grasha, Francesca Pinna, Stephen Hannon

Abstract:

The large number of star clusters in nearby galaxies permits us to statistically test the predictions of stellar, dust, and gas models. Using Hubble Space Telescope (HST) broadband plus Hα imaging combined with JWST near-infrared imaging, we use a total of 10 filters spanning near-ultraviolet through near-infrared wavelengths to model key physical parameters, including age, mass, and reddening, of 6130 star clusters in 16 nearby spiral galaxies from the Physics at High Angular resolution in Nearby GalaxieS sample, focusing on their ages, masses, and reddenings. We find that HST/Hα and JWST/NIRCam 2–3.6 μm photometry significantly improves our ability to disentangle the age–reddening degeneracy between young, gas- and dust-rich clusters and older, dustless clusters. The near-infrared data provide strong constraints on hot continuum dust and small polycyclic aromatic hydrocarbon emission for populations where gas and dust are present. These hot dust constraints demonstrate that Bruzual & Charlot stellar population models do not align with the observed near-ultraviolet-optical-near-infrared spectral energy distributions of star clusters in the first 10 Myr. We note that for old and low-metallicity globular clusters, the inclusion of narrowband Hα and/or broadband near-infrared data does not improve the determination of age and reddening parameters, due to the lack of stars capable of heating dust in the near-infrared regime.

Azimuthal offsets in spiral arms of nearby galaxies

Astronomy & Astrophysics EDP Sciences 701 (2025) a183

Authors:

Miguel Querejeta, Sharon E Meidt, Yixian Cao, Dario Colombo, Eric Emsellem, Santiago García-Burillo, Ralf S Klessen, Eric W Koch, Adam K Leroy, Marina Ruiz-García, Eva Schinnerer, Rowan Smith, Sophia Stuber, Mallory Thorp, Thomas G Williams, Médéric Boquien, Daniel A Dale, Chris Faesi, Damian R Gleis, Kathryn Grasha, Annie Hughes, María J Jiménez-Donaire, Kathryn Kreckel, Daizhong Liu, Justus Neumann, Hsi-An Pan, Francesca Pinna, Alessandro Razza, Toshiki Saito, Jiayi Sun, Antonio Usero

Abstract:

Spiral arms play a central role in disc galaxies, but their dynamical nature remains a long-standing open question. Azimuthal offsets between molecular gas and star formation are expected if gas crosses spiral arms, as predicted by quasi-stationary density wave theory. In this work, we measure offsets between CO and H α peaks in radial bins for 24 galaxies from the PHANGS survey that display a well-delineated spiral structure. The offsets exhibit substantial scatter, implying that star formation is not exclusively initiated at a coherent spiral shock. We define offsets such that positive values mean H α peaks lie ahead of CO peaks in the direction of galactic rotation. With this convention, 14 galaxies show mean positive CO-H α offsets, typically of a few hundred parsecs. In four of these 14 galaxies (17% of the total), offsets become smaller with increasing radius, as expected for a single quasi-stationary spiral density wave. Ten galaxies (42%) show positive mean offsets but no clear correlation with radius, which is compatible with multiple overlapping modes. In the remaining ten galaxies (42%), we find no significantly positive offsets, which could point to transient dynamical spirals or material arms, where gas and stars co-rotate with the spiral perturbation. Across the full sample, we find mostly positive offsets between CO peaks and the gravitational potential minimum, confirming that gas often crosses the spiral perturbation. For the four galaxies with clear positive offsets and a radial trend, we derived pattern speeds in good agreement with the literature. Overall, our results suggest that even well-delineated spirals in the local Universe can arise from a variety of underlying dynamical mechanisms.

WISDOM Project–XXVI. Cross-checking supermassive black hole mass estimates from ALMA CO gas kinematics and SINFONI stellar kinematics in the galaxy NGC 4751

Monthly Notices of the Royal Astronomical Society Oxford University Press 542:3 (2025) 2039-2059

Authors:

Pandora Dominiak, Michele Cappellari, Martin Bureau, Timothy A Davis, Marc Sarzi, Ilaria Ruffa, Satoru Iguchi, Thomas G Williams, Hengyue Zhang

Abstract:

We present high angular resolution (0.19 arcsec or pc) Atacama Large Millimeter/submillimeter Array observations of the CO(3–2) line emission of the galaxy NGC 4751. The data provide evidence for the presence of a central supermassive black hole (SMBH). Assuming a constant mass-to-light ratio (), we infer a SMBH mass M and a F160W filter stellar M/L, where the first uncertainties are statistical and the second systematic. Assuming a linearly spatially varying , we infer M and , where R is the galactocentric radius. We also present SMBH mass estimates using the Jeans Anisotropic Modelling (JAM) method and Very Large Telescope Spectrograph for INtegral Field Observations in the Near Infrared (SINFONI) stellar kinematics. Assuming a cylindrically aligned velocity ellipsoid (JAM), we infer M, and while assuming a spherically aligned velocity ellipsoid (JAM), we infer M. The SMBH mass assuming a constant is statistically consistent with that of JAM, whereas the mass assuming a linearly varying is consistent with both JAM and JAM (within the uncertainties). Our derived masses are larger than (and inconsistent with) one previous stellar dynamical measurement using the Schwarzschild orbit-superposition method and the same SINFONI kinematics.

A First Look at Spatially Resolved Infrared Supernova Remnants in M33 with JWST

The Astrophysical Journal American Astronomical Society 989:2 (2025) 138

Authors:

Sumit K Sarbadhicary, Erik Rosolowsky, Adam K Leroy, Thomas G Williams, Eric W Koch, Joshua Peltonen, Adam Smercina, Julianne J Dalcanton, Simon CO Glover, Margaret Lazzarini, Ryan Chown, Jennifer Donovan Meyer, Karin Sandstrom, Benjamin F Williams, Elizabeth Tarantino

Abstract:

We present the first spatially resolved infrared images of supernova remnants (SNRs) in M33 with the unprecedented sensitivity and resolution of JWST. We analyze 40 SNRs in four JWST fields: two covering central and southern M33 with separate NIRCam (F335M, F444W) and MIRI (F560W, F2100W) observations, one ∼5 kpc-long radial strip observed with MIRI F770W, and one covering the giant H II region NGC 604 with multiple NIRCam and MIRI broad/narrowband filters. Of the 21 SNRs in the MIRI (F560W+F2100W) field, we found three clear detections (i.e., identical infrared and Hα morphologies), and six partial-detections, implying a detection fraction of 43% in these bands. One of the SNRs in this field, L10-080, is a potential candidate for having freshly formed ejecta dust, based on its size and centrally concentrated 21 μm emission. In contrast, only one SNR (out of 16) is detectable in the NIRCam F335M+F444W field. Two SNRs near NGC 604 have strong evidence of molecular (H2) emission at 4.7 μm, making them the farthest known SNRs with visible molecular shocks. Five SNRs have F770W observations, with the smaller younger objects showing tentative signs of emission, while the older, larger ones have voids. Multiwavelength data indicate that the clearly detected SNRs are also among the smallest, brightest at other wavelengths (Hα, radio, and X-ray), have the broadest line widths (Hα FWHM ∼ 250–350 km s−1), and the densest environments. No correlation between the JWST-detectability and local star formation history of the SNRs is apparent.

PHANGS-HST Catalogs for ∼100,000 Star Clusters and Compact Associations in 38 Galaxies. II. Physical Properties from Decision-tree-based Spectral Energy Distribution Fitting of NUV- U - B - V - I Photometry with Categorical Priors Set by H α Emission, Cluster Morphology, and Other Auxiliary Information

The Astrophysical Journal: Supplement Series American Astronomical Society 280:1 (2025) 1

Authors:

David A Thilker, Janice C Lee, Bradley C Whitmore, Daniel Maschmann, Kiana Henny, Rupali Chandar, Daniel A Dale, Sinan Deger, Médéric Boquien, Aida Wofford, Leonardo Úbeda, Alessandro Razza, Ashley T Barnes, Francesco Belfiore, Frank Bigiel, Kathryn Grasha, Brent Groves, Hwihyun Kim, Ralf S Klessen, Justus Neumann, Francesca Pinna, M Jimena Rodríguez, Erik Rosolowsky, Eva Schinnerer, Thomas G Williams

Abstract:

This paper is the second in a series presenting the catalogs and properties of the largest sample to date of ∼100,000 star clusters and compact associations, in 38 spiral galaxies observed by the PHANGS-HST Treasury survey. Here, we present spectral energy distribution (SED) fitting techniques used to compute the age, mass, and reddening for each object. Our decision-tree-based strategy incorporates categorical priors on model age, reddening, and metallicity determined from additional observed parameters: localized Hα emission, source morphology, and demographic-specific locations in the UBVI color–color diagram. This approach is implemented to mitigate model degeneracies, particularly between young dusty clusters and old clusters with minimal dust, which can have identical optical colors. Results based on Hα narrowband imaging from the ground and from Hubble Space Telescope are intercompared, and contrasted with previous SED-fitting efforts. The fraction of the population that is subject to such priors is ∼14%, and of this subset, ∼63% of old globular clusters (GCs) have ages that change by a factor of 10 or more relative to unconstrained fits with single metallicity (Z⊙) simple stellar population models. The demographics of the population are examined through age–mass and age–reddening diagrams (for individual galaxies as well as aggregated over the sample), and the GC mass function. We demonstrate relationships between cluster age–mass diagrams and properties of parent galaxies (galaxy morphology and location relative to the galaxy main sequence). We outline continuing efforts to improve the inference of physical properties, including the incorporation of JWST infrared photometry and updated synthesis models.