Galaxy formation and evolution

Strong C iv emission from star-forming galaxies: a case for high Lyman continuum photon escape

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 517:1 (2022) 1098-1111

Authors:

A Saxena, E Cryer, RS Ellis, L Pentericci, A Calabrò, S Mascia, A Saldana-Lopez, D Schaerer, H Katz, M Llerena, R Amorín

The MOSDEF survey: a new view of a remarkable z = 1.89 merger

Monthly Notices of the Royal Astronomical Society Oxford University Press 517:3 (2022) 4405-4416

Authors:

Jordan N Runco, Alice E Shapley, Mariska Kriek, Michele Cappellari, Michael W Topping, Ryan L Sanders, Vasily I Kokorev, Sedona H Price, Naveen A Reddy, Alison L Coil, Bahram Mobasher, Brian Siana, Tom Zick, Georgios E Magdis, Gabriel Brammer, James Aird

Abstract:

We present a detailed study of a galaxy merger taking place at z = 1.89 in the GOODS-S field. Here, we analyse Keck/MOSFIRE spectroscopic observations from the MOSFIRE Deep Evolution Field (MOSDEF) survey along with multiwavelength photometry assembled by the 3D-HST survey. The combined data set is modelled to infer the past star formation histories (SFHs) of both merging galaxies. They are found to be massive, with log10(M*/M⊙) > 11, with a close mass ratio satisfying the typical major-merger definition. Additionally, in the context of delayed-τ models, GOODS-S 43114, and GOODS-S 43683 have similar SFHs and low star formation rates (log10(SFR(SED)/M⊙yr−1⁠) < 1.0) compared to their past averages. The best-fitting model SEDs show elevated H δA values for both galaxies, indicating that their stellar spectra are dominated by A-type stars, and that star formation peaked ∼0.5−1 Gyr ago and has recently declined. Additionally, based on SED fitting both merging galaxies turned on and shut off star formation within a few hundred Myr of each other, suggesting that their bursts of star formation may be linked. Combining the SFHs and H δA results with recent galaxy merger simulations, we infer that these galaxies have recently completed their first pericentric passage and are moving apart. Finally, the relatively low second velocity moment of GOODS-S 43114, given its stellar mass suggests a disc-like structure. However, including the geometry of the galaxy in the modelling does not completely resolve the discrepancy between the dynamical and stellar masses. Future work is needed to resolve this inconsistency in mass.

Torus and polar dust dependence on AGN properties

(2022)

Authors:

I García-Bernete, O González-Martín, C Ramos Almeida, A Alonso-Herrero, M Martínez-Paredes, MJ Ward, PF Roche, JA Acosta-Pulido, E López-Rodríguez, D Rigopoulou, D Esparza-Arredondo

WISDOM Project – XII. Clump properties and turbulence regulated by clump–clump collisions in the dwarf galaxy NGC 404

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 517:1 (2022) 632-656

Authors:

Lijie Liu, Martin Bureau, Guang-Xing Li, Timothy A Davis, Dieu D Nguyen, Fu-Heng Liang, Woorak Choi, Mark R Smith, Satoru Iguchi

Abstract:

ABSTRACT We present a study of molecular structures (clumps and clouds) in the dwarf galaxy NGC 404 using high-resolution (≈0.86 × 0.51 pc2) Atacama Large Millimeter/sub-millimeter Array 12CO(2-1) observations. We find two distinct regions in NGC 404: a gravitationally stable central region (Toomre parameter Q = 3–30) and a gravitationally unstable molecular ring (Q ≲ 1). The molecular structures in the central region have a steeper size–linewidth relation and larger virial parameters than those in the molecular ring, suggesting gas is more turbulent in the former. In the molecular ring, clumps exhibit a shallower mass–size relation and larger virial parameters than clouds, implying density structures and dynamics are regulated by different physical mechanisms at different spatial scales. We construct an analytical model of clump–clump collisions to explain the results in the molecular ring. We propose that clump–clump collisions are driven by gravitational instabilities coupled with galactic shear, which lead to a population of clumps whose accumulation lengths (i.e. average separations) are approximately equal to their tidal radii. Our model-predicted clump masses and sizes (and mass–size relation) and turbulence energy injection rates (and size–linewidth relation) match the observations in the molecular ring very well, suggesting clump–clump collisions are the main mechanism regulating clump properties and gas turbulence in that region. As expected, our collision model does not apply to the central region, where turbulence is likely driven by clump migration.

The Population of Viscosity- and Gravitational Wave-driven Supermassive Black Hole Binaries among Luminous Active Galactic Nuclei (vol 700, 1952, 2009)

ASTROPHYSICAL JOURNAL American Astronomical Society 937:2 (2022) ARTN 129

Authors:

Zoltan Haiman, Bence Kocsis, Kristen Menou

Abstract:

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