Galaxy formation and evolution

VINTERGATAN – II. The history of the Milky Way told by its mergers

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 503:4 (2021) 5846-5867

Authors:

Florent Renaud, Oscar Agertz, Justin I Read, Nils Ryde, Eric P Andersson, Thomas Bensby, Martin P Rey, Diane K Feuillet

Abstract:

ABSTRACT Using the VINTERGATAN cosmological zoom simulation, we explore the contributions of the in situ and accreted material, and the effect of galaxy interactions and mergers in the assembly of a Milky Way-like galaxy. We find that the initial growth phase of galaxy evolution, dominated by repeated major mergers, provides the necessary physical conditions for the assembly of a thick, kinematically hot disc populated by high-[α/Fe] stars, formed both in situ and in accreted satellite galaxies. We find that the diversity of evolutionary tracks followed by the simulated galaxy and its progenitors leads to very little overlap of the in situ and accreted populations for any given chemical composition. At a given age, the spread in [α/Fe] abundance ratio results from the diversity of physical conditions in VINTERGATAN and its satellites, with an enhancement in [α/Fe] found in stars formed during starburst episodes. Later, the cessation of the merger activity promotes the in situ formation of stars in the low-[α/Fe] regime, in a radially extended, thin and overall kinematically colder disc, thus establishing chemically bimodal thin and thick discs, in line with observations. We draw links between notable features in the [Fe/H]-[α/Fe] plane with their physical causes, and propose a comprehensive formation scenario explaining self-consistently, in the cosmological context, the main observed properties of the Milky Way.

Integral field spectroscopy of luminous infrared main-sequence galaxies at cosmic noon

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 503:4 (2021) 5329-5350

Authors:

L Hogan, D Rigopoulou, GE Magdis, M Pereira-Santaella, I García-Bernete, N Thatte, K Grisdale, J-S Huang

Multifrequency observations of SGR J1935+2154

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 503:4 (2021) 5367-5384

Authors:

M Bailes, CG Bassa, G Bernardi, S Buchner, M Burgay, M Caleb, AJ Cooper, G Desvignes, PJ Groot, I Heywood, F Jankowski, R Karuppusamy, M Kramer, M Malenta, G Naldi, M Pilia, G Pupillo, KM Rajwade, L Spitler, M Surnis, BW Stappers, A Addis, S Bloemen, MC Bezuidenhout, G Bianchi, DJ Champion, W Chen, LN Driessen, M Geyer, K Gourdji, JWT Hessels, VI Kondratiev, M Klein-Wolt, E Körding, R Le Poole, K Liu, ME Lower, AG Lyne, A Magro, V McBride, MB Mickaliger, V Morello, A Parthasarathy, K Paterson, BBP Perera, DLA Pieterse, Z Pleunis, A Possenti, A Rowlinson, M Serylak, G Setti, M Tavani, RAMJ Wijers, S ter Veen, V Venkatraman Krishnan, P Vreeswijk, PA Woudt

The properties of polycyclic aromatic hydrocarbons in galaxies: constraints on PAH sizes, charge and radiation fields

Monthly Notices of the Royal Astronomical Society Oxford University Press 504:4 (2021) 5287-5300

Authors:

D Rigopoulou, M Barale, Dc Clary, X Shan, A Alonso-Herrero, I Garcia-Bernete, L Hunt, B Kerkeni, M Pereira-Santaella, Pf Roche

Abstract:

Based on theoretical spectra computed using Density Functional Theory we study the properties of polycyclic aromatic hydrocarbons (PAH). In particular using bin-average spectra of PAH molecules with varying number of carbons we investigate how the intensity of the mid-infrared emission bands, 3.3, 6.2, 7.7, and 11.3 $\mu$m, respond to changes in the number of carbons, charge of the molecule, and the hardness of the radiation field that impinges the molecule. We confirm that the 6.2/7.7 band ratio is a good predictor for the size of the PAH molecule (based on the number of carbons present). We also investigate the efficacy of the 11.3/3.3 ratio to trace the size of PAH molecules and note the dependence of this ratio on the hardness of the radiation field. While the ratio can potentially also be used to trace PAH molecular size, a better understanding of the impact of the underlying radiation field on the 3.3 $\mu$m feature and the effect of the extinction on the ratio should be evaluated. The newly developed diagnostics are compared to band ratios measured in a variety of galaxies observed with the Infrared Spectrograph on board the Spitzer Space Telescope. We demonstrate that the band ratios can be used to probe the conditions of the interstellar medium in galaxies and differentiate between environments encountered in normal star forming galaxies and active galactic nuclei. Our work highlights the immense potential that PAH observations with the James Webb Space Telescope will have on our understanding of the PAH emission itself and of the physical conditions in galaxies near and far.

Unraveling the origin of magnetic fields in galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press 504:2 (2021) 2517–2534

Authors:

Sergio Martin-Alvarez, Harley Katz, Debora Sijacki, Julien Devriendt, Adrianne Slyz

Abstract:

Despite their ubiquity, there are many open questions regarding galactic and cosmic magnetic fields. Specifically, current observational constraints cannot rule out whether magnetic fields observed in galaxies were generated in the early Universe or are of astrophysical nature. Motivated by this, we use our magnetic tracer algorithm to investigate whether the signatures of primordial magnetic fields persist in galaxies throughout cosmic time. We simulate a Milky Way-like galaxy down to z ∼ 2–1 in four scenarios: magnetized solely by primordial magnetic fields, magnetized exclusively by supernova (SN)-injected magnetic fields, and two combined primordial + SN magnetization cases. We find that once primordial magnetic fields with a comoving strength B0 > 10−12 G are considered, they remain the primary source of galaxy magnetization. Our magnetic tracers show that, even combined with galactic sources of magnetization, when primordial magnetic fields are strong, they source the large-scale fields in the warm metal-poor phase of the simulated galaxy. In this case, the circumgalactic medium and intergalactic medium can be used to probe B0 without risk of pollution by magnetic fields originated in the galaxy. Furthermore, whether magnetic fields are primordial or astrophysically sourced can be inferred by studying local gas metallicity. As a result, we predict that future state-of-the-art observational facilities of magnetic fields in galaxies will have the potential to unravel astrophysical and primordial magnetic components of our Universe.