Galaxy formation and evolution

First detection of the 448 GHz H2O transition in space

Astronomy & Astrophysics EDP Sciences 601 (2017) L3

Authors:

Miguel Pereira-Santaella, E González-Alfonso, A Usero, S García-Burillo, J Martín-Pintado, L Colina, A Alonso-Herrero, S Arribas, S Cazzoli, F Rico, Dimitra Rigopoulou, T Storchi Storchi Bergmann

Abstract:

We present the first detection of the ortho-H2O 4₂₃ - 3₃₀ transition at 448 GHz in space. We observed this transition in the local (z = 0.010) luminous infrared (IR) galaxy ESO 320-G030 (IRAS F11506-3851) using the Atacama Large Millimeter/submillimeter Array (ALMA). The water 4₂₃ - 3₃₀ emission, which originates in the highly obscured nucleus of this galaxy, is spatially resolved over a region of ~65 pc in diameter and shows a regular rotation pattern compatible with the global molecular and ionized gas kinematics. The line profile is symmetric and well fitted by a Gaussian with an integrated flux of 37.0 ± 0.7 Jy km s^-1 . Models predict this water transition as a potential collisionally excited maser transition. On the contrary, in this galaxy, we find that the 4₂₃ - 3₃₀ emission is primarily excited by the intense far-IR radiation field present in its nucleus. According to our modeling, this transition is a probe of deeply buried galaxy nuclei thanks to the high dust optical depths (τ 100μm > 1, NH > 10^24 cm^-2 ) required to efficiently excite it.

Fluctuating feedback-regulated escape fraction of ionizing radiation in low-mass, high-redshift galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press 470:1 (2017) 224-239

Authors:

M Trebitsch, J Blaizot, J Rosdahl, Julien Devriendt, Adrienne Slyz

Abstract:

Low-mass galaxies are thought to provide the bulk of the ionizing radiation necessary to reionize the Universe. The amount of photons escaping the galaxies is poorly constrained theoretically, and difficult to measure observationally. Yet it is an essential parameter of reionization models.We study in detail how ionizing radiation can leak from high-redshift galaxies. For this purpose, we use a series of high-resolution radiation hydrodynamics simulations, zooming on three dwarf galaxies in a cosmological context. We find that the energy and momentum input from the supernova explosions has a pivotal role in regulating the escape fraction by disrupting dense star-forming clumps, and clearing sightlines in the halo. In the absence of supernovae, photons are absorbed very locally, within the birth clouds of massive stars. We follow the time evolution of the escape fraction and find that it can vary by more than six orders of magnitude. This explains the large scatter in the value of the escape fraction found by previous studies. This fast variability also impacts the observability of the sources of reionization: a survey even as deep as M 1500 = -14 would miss about half of the underlying population of Lyman-continuum emitters.

Galaxy Zoo: Finding offset discs and bars in SDSS galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press 469:3 (2017) 3363-3373

Authors:

Sandor I Kruk, Christopher J Lintott, Brooke D Simmons, SP Bamford, CN Cardamone, L Fortson, RE Hart, B Häußler, KL Masters, RC Nichol, K Schawinski, Rebecca J Smethurst

Abstract:

We use multi-wavelength SDSS images and Galaxy Zoo morphologies to identify a sample of $\sim$$270$ late-type galaxies with an off-centre bar. We measure offsets in the range 0.2-2.5 kpc between the photometric centres of the stellar disc and stellar bar. The measured offsets correlate with global asymmetries of the galaxies, with those with largest offsets showing higher lopsidedness. These findings are in good agreement with predictions from simulations of dwarf-dwarf tidal interactions producing off-centre bars. We find that the majority of galaxies with off-centre bars are of Magellanic type, with a median mass of $10^{9.6} M_{\odot}$, and 91% of them having $M_{\star}<3\times10^{10} M_{\odot}$, the characteristic mass at which galaxies start having higher central concentrations attributed to the presence of bulges. We conduct a search for companions to test the hypothesis of tidal interactions, but find that a similar fraction of galaxies with offset bars have companions within 100 kpc as galaxies with centred bars. Although this may be due to the incompleteness of the SDSS spectroscopic survey at the faint end, alternative scenarios that give rise to offset bars such as interactions with dark companions or the effect of lopsided halo potentials should be considered. Future observations are needed to confirm possible low mass companion candidates and to determine the shape of the dark matter halo, in order to find the explanation for the off-centre bars in these galaxies.

Stacked Average Far-Infrared Spectrum of Dusty Star-Forming Galaxies from the Herschel/SPIRE Fourier Transform Spectrometer

(2017)

Authors:

Derek Wilson, Asantha Cooray, Hooshang Nayyeri, Matteo Bonato, Charles M Bradford, David L Clements, Gianfranco De Zotti, Tanio Díaz-Santos, Duncan Farrah, Georgios Magdis, Michał J Michałowski, Chris Pearson, Dimitra Rigopoulou, Ivan Valtchanov, Lingyu Wang, Julie Wardlow

The LOFAR window on star-forming galaxies and AGNs – curved radio SEDs and IR–radio correlation at 0

Monthly Notices of the Royal Astronomical Society Oxford University Press 469:3 (2017) 3468-3488

Authors:

G Calistro Rivera, WL Williams, MJ Hardcastle, K Duncan, HJA Röttgering, PN Best, M Brüggen, KT Chyży, CJ Conselice, F de Gasperin, D Engels, G Gürkan, HT Intema, Matthew Jarvis, EK Mahony, GK Miley, Leah K Morabito, I Prandoni, J Sabater, DJB Smith, C Tasse, PP van der Werf, GJ White

Abstract:

We present a study of the low-frequency radio properties of star-forming (SF) galaxies and active galactic nuclei (AGNs) up to redshift z = 2.5. The new spectral window probed by the Low Frequency Array (LOFAR) allows us to reconstruct the radio continuum emission from 150 MHz to 1.4 GHz to an unprecedented depth for a radio-selected sample of 1542 galaxies in ∼ 7 deg2 of the LOFAR Boötes field. Using the extensive multiwavelength data set available in Boötes and detailed modelling of the far-infrared to ultraviolet spectral energy distribution (SED), we are able to separate the star formation (N = 758) and the AGN (N = 784) dominated populations. We study the shape of the radio SEDs and their evolution across cosmic time and find significant differences in the spectral curvature between the SF galaxy and AGN populations. While the radio spectra of SF galaxies exhibit a weak but statistically significant flattening, AGN SEDs show a clear trend to become steeper towards lower frequencies. No evolution of the spectral curvature as a function of redshift is found for SF galaxies or AGNs. We investigate the redshift evolution of the infrared–radio correlation for SF galaxies and find that the ratio of total infrared to 1.4-GHz radio luminosities decreases with increasing redshift: q1.4 GHz = (2.45 ± 0.04) (1 + z)−0.15 ± 0.03. Similarly, q150 MHz shows a redshift evolution following q150 GHz = (1.72 ± 0.04) (1 + z)−0.22 ± 0.05. Calibration of the 150 MHz radio luminosity as a star formation rate tracer suggests that a single power-law extrapolation from q1.4 GHz is not an accurate approximation at all redshifts.