Galaxy formation and evolution

Resolved Neutral Outflow from a Lensed Dusty Star-forming Galaxy at z = 2.09

The Astrophysical Journal American Astronomical Society 919:1 (2021) 5

Authors:

Kirsty M Butler, Paul P van der Werf, Matus Rybak, Tiago Costa, Pierre Cox, Axel Weiß, Michał J Michałowski, Dominik A Riechers, Dimitra Rigopoulou, Lucia Marchetti, Stephen Eales, Ivan Valtchanov

Normal, dust-obscured galaxies in the epoch of reionization.

Nature 597:7877 (2021) 489-492

Authors:

Y Fudamoto, PA Oesch, S Schouws, M Stefanon, R Smit, RJ Bouwens, RAA Bowler, R Endsley, V Gonzalez, H Inami, I Labbe, D Stark, M Aravena, L Barrufet, E da Cunha, P Dayal, A Ferrara, L Graziani, J Hodge, A Hutter, Y Li, I De Looze, T Nanayakkara, A Pallottini, D Riechers, R Schneider, G Ucci, P van der Werf, C White

Abstract:

Over the past decades, rest-frame ultraviolet (UV) observations have provided large samples of UV luminous galaxies at redshift (z) greater than 6 (refs. ^1-3), during the so-called epoch of reionization. While a few of these UV-identified galaxies revealed substantial dust reservoirs^4-7, very heavily dust-obscured sources at these early times have remained elusive. They are limited to a rare population of extreme starburst galaxies^8-12 and companions of rare quasars^13,14. These studies conclude that the contribution of dust-obscured galaxies to the cosmic star formation rate density at z > 6 is sub-dominant. Recent ALMA and Spitzer observations have identified a more abundant, less extreme population of obscured galaxies at z = 3-6 (refs. ^15,16). However, this population has not been confirmed in the reionization epoch so far. Here, we report the discovery of two dust-obscured star-forming galaxies at z = 6.6813 ± 0.0005 and z = 7.3521 ± 0.0005. These objects are not detected in existing rest-frame UV data and were discovered only through their far-infrared [C II] lines and dust continuum emission as companions to typical UV-luminous galaxies at the same redshift. The two galaxies exhibit lower infrared luminosities and star-formation rates than extreme starbursts, in line with typical star-forming galaxies at z ≈ 7. This population of heavily dust-obscured galaxies appears to contribute 10-25% to the z > 6 cosmic star formation rate density.

The ALPINE-ALMA [CII] survey

Astronomy & Astrophysics EDP Sciences 653 (2021) a84

Authors:

F Pozzi, F Calura, Y Fudamoto, M Dessauges-Zavadsky, C Gruppioni, M Talia, G Zamorani, M Bethermin, A Cimatti, A Enia, Y Khusanova, R Decarli, O Le Fèvre, P Capak, P Cassata, AL Faisst, L Yan, D Schaerer, J Silverman, S Bardelli, M Boquien, A Enia, D Narayanan, M Ginolfi, NP Hathi, GC Jones, AM Koekemoer, BC Lemaux, F Loiacono, R Maiolino, DA Riechers, G Rodighiero, M Romano, L Vallini, D Vergani, E Zucca

The ALPINE-ALMA [CII] survey

Astronomy & Astrophysics EDP Sciences 653 (2021) a111

Authors:

M Romano, P Cassata, L Morselli, GC Jones, M Ginolfi, A Zanella, M Béthermin, P Capak, A Faisst, O Le Fèvre, D Schaerer, JD Silverman, L Yan, S Bardelli, M Boquien, A Cimatti, M Dessauges-Zavadsky, A Enia, S Fujimoto, C Gruppioni, NP Hathi, E Ibar, AM Koekemoer, BC Lemaux, G Rodighiero, D Vergani, G Zamorani, E Zucca

Stellar dynamics in the periodic cube

Monthly Notices of the Royal Astronomical Society Oxford University Press 507:4 (2021) 4840-4851

Abstract:

We use the problem of dynamical friction within the periodic cube to illustrate the application of perturbation theory in stellar dynamics, testing its predictions against measurements from N-body simulations. Our development is based on the explicitly time-dependent Volterra integral equation for the cube’s linear response, which avoids the subtleties encountered in analyses based on complex frequency. We obtain an expression for the self-consistent response of the cube to steady stirring by an external perturber. From this, we show how to obtain the familiar Chandrasekhar dynamical friction formula and construct an elementary derivation of the Lenard–Balescu equation for the secular quasi-linear evolution of an isolated cube composed of N equal-mass stars. We present an alternative expression for the (real-frequency) van Kampen modes of the cube and show explicitly how to decompose any linear perturbation of the cube into a superposition of such modes.