Your search keyword '"McElroy, Rebecca"' showing total 3 results

1. Environmental dependence of the molecular cloud lifecycle in 54 main-sequence galaxies.

Author

Kim, Jaeyeon, Chevance, Mélanie, Kruijssen, J M Diederik, Leroy, Adam K, Schruba, Andreas, Barnes, Ashley T, Bigiel, Frank, Blanc, Guillermo A, Cao, Yixian, Congiu, Enrico, Dale, Daniel A, Faesi, Christopher M, Glover, Simon C O, Grasha, Kathryn, Groves, Brent, Hughes, Annie, Klessen, Ralf S, Kreckel, Kathryn, McElroy, Rebecca, and Pan, Hsi-An

Subjects

STELLAR evolution, GALAXIES, MOLECULAR clouds, GALACTIC evolution, STAR formation, GIANT stars

Abstract

The processes of star formation and feedback, regulating the cycle of matter between gas and stars on the scales of giant molecular clouds (GMCs; ∼100 pc), play a major role in governing galaxy evolution. Measuring the time-scales of GMC evolution is important to identify and characterize the specific physical mechanisms that drive this transition. By applying a robust statistical method to high-resolution CO and narrow-band H α imaging from the PHANGS survey, we systematically measure the evolutionary timeline from molecular clouds to exposed young stellar regions on GMC scales, across the discs of an unprecedented sample of 54 star-forming main-sequence galaxies (excluding their unresolved centres). We find that clouds live for about 1−3 GMC turbulence crossing times (5−30 Myr) and are efficiently dispersed by stellar feedback within 1−5 Myr once the star-forming region becomes partially exposed, resulting in integrated star formation efficiencies of 1−8 per cent. These ranges reflect physical galaxy-to-galaxy variation. In order to evaluate whether galactic environment influences GMC evolution, we correlate our measurements with average properties of the GMCs and their local galactic environment. We find several strong correlations that can be physically understood, revealing a quantitative link between galactic-scale environmental properties and the small-scale GMC evolution. Notably, the measured CO-visible cloud lifetimes become shorter with decreasing galaxy mass, mostly due to the increasing presence of CO-dark molecular gas in such environment. Our results represent a first step towards a comprehensive picture of cloud assembly and dispersal, which requires further extension and refinement with tracers of the atomic gas, dust, and deeply embedded stars. [ABSTRACT FROM AUTHOR]

Published

2022

2. PHANGS–MUSE: The H II region luminosity function of local star-forming galaxies.

Author

Santoro, Francesco, Kreckel, Kathryn, Belfiore, Francesco, Groves, Brent, Congiu, Enrico, Thilker, David A., Blanc, Guillermo A., Schinnerer, Eva, Ho, I-Ting, Diederik Kruijssen, J. M., Meidt, Sharon, Klessen, Ralf S., Schruba, Andreas, Querejeta, Miguel, Pessa, Ismael, Chevance, Mélanie, Kim, Jaeyeon, Emsellem, Eric, McElroy, Rebecca, and Barnes, Ashley T.

Subjects

SPIRAL galaxies, GALAXIES, MAIN sequence (Astronomy), LUMINOSITY, STAR formation, STAR clusters

Abstract

We use an unprecedented sample of about 23 000 H II regions detected at an average physical resolution of 67 pc in the PHANGS–MUSE sample to study the extragalactic H II region Hα luminosity function (LF). Our observations probe the star-forming disk of 19 nearby spiral galaxies with low inclination and located close to the star formation main sequence at z = 0. The mean LF slope, α, in our sample is =1.73 with a σ of 0.15. We find that α decreases with the galaxy's star formation rate surface density, ΣSFR, and argue that this is driven by an enhanced clustering of young stars at high gas surface densities. Looking at the H II regions within single galaxies, we find that no significant variations occur between the LF of the inner and outer part of the star-forming disk, whereas the LF in the spiral arm areas is shallower than in the inter-arm areas for six out of the 13 galaxies with clearly visible spiral arms. We attribute these variations to the spiral arms increasing the molecular clouds' arm–inter-arm mass contrast and find suggestive evidence that they are more evident for galaxies with stronger spiral arms. Furthermore, we find systematic variations in α between samples of H II regions with a high and low ionization parameter, q, and argue that they are driven by the aging of H II regions. [ABSTRACT FROM AUTHOR]

Published

2022

3. Measuring the mixing scale of the ISM within nearby spiral galaxies.

Author

Kreckel, Kathryn, Ho, I-Ting, Blanc, Guillermo A, Glover, Simon C O, Groves, Brent, Rosolowsky, Erik, Bigiel, Frank, Boquíen, Médéric, Chevance, Mélanie, Dale, Daniel A, Deger, Sinan, Emsellem, Eric, Grasha, Kathryn, Kim, Jenny J, Klessen, Ralf S, Kruijssen, J M Diederik, Lee, Janice C, Leroy, Adam K, Liu, Daizhong, and McElroy, Rebecca

Subjects

INTEGRAL field spectroscopy, CHEMICAL processes, DISK galaxies, IONIZED gases, STAR formation

Abstract

The spatial distribution of metals reflects, and can be used to constrain, the processes of chemical enrichment and mixing. Using PHANGS-MUSE optical integral field spectroscopy, we measure the gas-phase oxygen abundances (metallicities) across 7138 H  ii regions in a sample of eight nearby disc galaxies. In Paper I, we measure and report linear radial gradients in the metallicities of each galaxy, and qualitatively searched for azimuthal abundance variations. Here, we examine the 2D variation in abundances once the radial gradient is subtracted, Δ(O/H), in order to quantify the homogeneity of the metal distribution and to measure the mixing scale over which H  ii region metallicities are correlated. We observe low (0.03–0.05 dex) scatter in Δ(O/H) globally in all galaxies, with significantly lower (0.02–0.03 dex) scatter on small (<600 pc) spatial scales. This is consistent with the measurement uncertainties, and implies the 2D metallicity distribution is highly correlated on scales of ≲600 pc. We compute the two-point correlation function for metals in the disc in order to quantify the scale lengths associated with the observed homogeneity. This mixing scale is observed to correlate better with the local gas velocity dispersion (of both cold and ionized gas) than with the star formation rate. Selecting only H  ii regions with enhanced abundances relative to a linear radial gradient, we do not observe increased homogeneity on small scales. This suggests that the observed homogeneity is driven by the mixing introducing material from large scales rather than by pollution from recent and on-going star formation. [ABSTRACT FROM AUTHOR]

Published

2020