Your search keyword '"Davis, Julie D."' showing total 4 results

1. Extending the Dynamic Range of Galaxy Outflow Scaling Relations: Massive Compact Galaxies with Extreme Outflows.

Author

Davis, Julie D., Tremonti, Christy A., Swiggum, Cameren N., Moustakas, John, Diamond-Stanic, Aleksandar M., Coil, Alison L., Geach, James E., Hickox, Ryan C., Perrotta, Serena, Petter, Grayson C., Rudnick, Gregory H., Rupke, David S. N., Sell, Paul H., and Whalen, Kelly E.

Subjects

*GALAXIES, *STAR formation, *BLACK holes, *WIND speed, *OPTICAL spectra, *STELLAR mass, *GALAXY mergers

Abstract

We investigate galactic winds in the HizEA galaxies, a collection of 46 late-stage galaxy mergers at z = 0.4–0.8, with stellar masses of log (M * / M ⊙) = 10.4 – 11.5 , star formation rates (SFRs) of 20–500 M ⊙ yr−1, and ultra-compact (a few 100 pc) central star-forming regions. We measure their gas kinematics using the Mg ii λ λ 2796,2803 absorption lines in optical spectra from MMT, Magellan, and Keck. We find evidence of outflows in 90% of targets, with maximum outflow velocities of 550–3200 km s−1. We combine these data with ten samples from the literature to construct scaling relations for outflow velocity versus SFR, star formation surface density (ΣSFR), M *, and SFR/ M *. The HizEA galaxies extend the dynamic range of the scaling relations by a factor of ∼2–4 in outflow velocity and an order of magnitude in SFR and ΣSFR. The ensemble scaling relations exhibit strong correlations between outflow velocity, SFR, SFR/ R, and ΣSFR, and weaker correlations with M * and SFR/ M *. The HizEA galaxies are mild outliers on the SFR and M * scaling relations, but they connect smoothly with more typical star-forming galaxies on plots of outflow velocity versus SFR/ R and ΣSFR. These results provide further evidence that the HizEA galaxies' exceptional outflow velocities are a consequence of their extreme star formation conditions rather than hidden black hole activity, and they strengthen previous claims that ΣSFR is one of the most important properties governing the velocities of galactic winds. [ABSTRACT FROM AUTHOR]

Published

2023

2. Kinematics, Structure, and Mass Outflow Rates of Extreme Starburst Galactic Outflows.

Author

Perrotta, Serena, Coil, Alison L., Rupke, David S. N., Tremonti, Christy A., Davis, Julie D., Diamond-Stanic, Aleksandar M., Geach, James E., Hickox, Ryan C., Moustakas, John, Rudnick, Gregory H., Sell, Paul H., Swiggum, Cameren N., and Whalen, Kelly E.

Subjects

KINEMATICS, STAR formation, STARBURSTS, TURBULENT mixing, GALACTIC evolution, COLUMNS

Abstract

We present results on the properties of extreme gas outflows in massive (M * ∼ 1011 M ⊙), compact, starburst (star formation rate, SFR∼ 200 M ⊙ yr−1) galaxies at z = 0.4–0.7 with very high star formation surface densities (ΣSFR ∼ 2000 M ⊙ yr−1 kpc−2). Using optical Keck/HIRES spectroscopy of 14 HizEA starburst galaxies, we identify outflows with maximum velocities of 820–2860 km s−1. High-resolution spectroscopy allows us to measure precise column densities and covering fractions as a function of outflow velocity and characterize the kinematics and structure of the cool gas outflow phase (T ∼ 104 K). We find substantial variation in the absorption profiles, which likely reflects the complex morphology of inhomogeneously distributed, clumpy gas and the intricacy of the turbulent mixing layers between the cold and hot outflow phases. There is not a straightforward correlation between the bursts in the galaxies' star formation histories and their wind absorption line profiles, as might naively be expected for starburst-driven winds. The lack of strong Mg ii absorption at the systemic velocity is likely an orientation effect, where the observations are down the axis of a blowout. We infer high mass outflow rates of ∼50–2200 M ⊙ yr−1, assuming a fiducial outflow size of 5 kpc, and mass loading factors of η ∼ 5 for most of the sample. While these values have high uncertainties, they suggest that starburst galaxies are capable of ejecting very large amounts of cool gas that will substantially impact their future evolution. [ABSTRACT FROM AUTHOR]

Published

2023

3. Compact Starburst Galaxies with Fast Outflows: Central Escape Velocities and Stellar Mass Surface Densities from Multiband Hubble Space Telescope Imaging.

Author

Diamond-Stanic, Aleksandar M., Moustakas, John, Sell, Paul H., Tremonti, Christy A., Coil, Alison L., Davis, Julie D., Geach, James E., Gottlieb, Sophia C. W., Hickox, Ryan C., Kepley, Amanda, Lipscomb, Charles, Rines, Joshua, Rudnick, Gregory H., Thompson, Cristopher, Valdez, Kingdell, Bradna, Christian, Camarillo, Jordan, Cinquino, Eve, Ohene, Senyo, and Perrotta, Serena

Subjects

STELLAR density (Stellar population), SPACE telescopes, EDDINGTON mass limit, STELLAR mass, STARBURSTS, VELOCITY

Abstract

We present multiband Hubble Space Telescope imaging that spans rest-frame near-ultraviolet through near-infrared wavelengths (–1.1 μm) for 12 compact starburst galaxies at z = 0.4–0.8. These massive galaxies () are driving very fast outflows (–3000 km s−1), and their light profiles are dominated by an extremely compact starburst component (half-light radius ∼ 100 pc). Our goal is to constrain the physical mechanisms responsible for launching these fast outflows by measuring the physical conditions within the central kiloparsec. Based on our stellar population analysis, the central component typically contributes ≈25% of the total stellar mass, and the central escape velocities km s−1 are a factor of two smaller than the observed outflow velocities. This Requires physical mechanisms that can accelerate gas to speeds significantly beyond the central escape velocities, and it makes clear that these fast outflows are capable of traveling into the circumgalactic medium, and potentially beyond. We find central stellar densities kpc−2 comparable to theoretical estimates of the Eddington limit, and we estimate surface densities within the central kiloparsec comparable to those of compact massive galaxies at. Relative to "red nuggets" and "blue nuggets" at , we find significantly smaller re values at a given stellar mass, which we attribute to the dominance of a young stellar component in our sample and the better physical resolution for rest-frame optical observations at versus. We compare to theoretical scenarios involving major mergers and violent disk instability, and we speculate that our galaxies are progenitors of power-law ellipticals in the local universe with prominent stellar cusps. [ABSTRACT FROM AUTHOR]

Published

2021

4. Deviations from the Infrared-radio Correlation in Massive, Ultracompact Starburst Galaxies.

Author

Petter, Grayson C., Kepley, Amanda A., Hickox, Ryan C., Rudnick, Gregory H., Tremonti, Christy A., Diamond-Stanic, Aleksandar M., Geach, James E., Coil, Alison L., Sell, Paul H., Moustakas, John, Rupke, David S. N., Perrotta, Serena, Whalen, Kelly E., and Davis, Julie D.

Subjects

EDDINGTON mass limit, RADIATION pressure, GALAXY mergers, SYNCHROTRON radiation, STAR formation, STARBURSTS

Abstract

Feedback through energetic outflows has emerged as a key physical process responsible for transforming star-forming galaxies into the quiescent systems observed in the local universe. To explore this process, this paper focuses on a sample of massive and compact merger remnant galaxies hosting high-velocity gaseous outflows (km s−1), found at intermediate redshift (z ∼ 0.6). From their mid-infrared emission and compact morphologies, these galaxies are estimated to have exceptionally large star formation rate (SFR) surface densities (ΣSFR ∼ 103M⊙ yr−1 kpc−2), approaching the Eddington limit for radiation pressure on dust grains. This suggests that star formation feedback may be driving the observed outflows. However, these SFR estimates suffer from significant uncertainties. We therefore sought an independent tracer of star formation to probe the compact starburst activity in these systems. In this paper, we present SFR estimates calculated using 1.5 GHz continuum Jansky Very Large Array observations for 19 of these galaxies. We also present updated infrared (IR) SFRs calculated from WISE survey data. We estimate SFRs from the IR to be larger than those from the radio for 16 out of 19 galaxies by a median factor of 2.5. We find that this deviation is maximized for the most compact galaxies hosting the youngest stellar populations, suggesting that compact starbursts deviate from the IR-radio correlation. We suggest that this deviation stems either from free–free absorption of synchrotron emission, a difference in the timescale over which each indicator traces star formation, or exceptionally hot IR-emitting dust in these ultra-dense galaxies. [ABSTRACT FROM AUTHOR]

Published

2020