Cosmology

Cosmological simulations of the same spiral galaxy: connecting the dark matter distribution of the host halo with the subgrid baryonic physics

Journal of Cosmology and Astroparticle Physics IOP Publishing 2023:5 (2023) 012

Authors:

A Nuñez-Castiñeyra, E Nezri, P Mollitor, J Devriendt, R Teyssier

Abstract:

The role of baryonic physics, star formation and stellar feedback, in shaping the galaxies and their host halos is an evolving topic. The dark matter aspects are illustrated in this work by showing distribution features in a Milky Way sized halo. We focus on the halo morphology, geometry, and profile as well as the phase space distribution using one dark matter only and five hydrodynamical cosmological high-resolution simulations of the same halo with different subgrid prescriptions for the baryonic physics (Kennicut versus multi-freefall star formation and delayed cooling versus mechanical supernovae feedback). If some general properties like the relative halo-galaxy orientation are similar, the modifications of the gravitational potential due to the presence of baryons are found to induce different dark matter distributions (rounder and more concentrated halo). The mass density profile as well as the velocity distribution are modified distinctively according to the specific resulting baryonic distribution highlighting the variability of those properties (e.g inner power index from 1.3 to 1.8, broader speed distribution). The uncertainties on those features are of paramount importance for dark matter phenomenology, particularly when dealing with dark matter dynamics or direct and indirect detection searches. As a consequence, dark matter properties and prospects using cosmological simulations require improvement on baryonic physics description. Modeling such processes is a key issue not only for galaxy formation but also for dark matter investigations.

Identification and properties of intense star-forming galaxies at redshifts z > 10

Nature Astronomy Springer Nature 7:5 (2023) 611-621

Authors:

BE Robertson, S Tacchella, BD Johnson, K Hainline, L Whitler, DJ Eisenstein, R Endsley, M Rieke, DP Stark, S Alberts, A Dressler, E Egami, R Hausen, G Rieke, I Shivaei, CC Williams, CNA Willmer, S Arribas, N Bonaventura, A Bunker, AJ Cameron, S Carniani, S Charlot, J Chevallard, M Curti, E Curtis-Lake, F D’Eugenio, P Jakobsen, TJ Looser, N Lützgendorf, R Maiolino, MV Maseda, T Rawle, H-W Rix, R Smit, H Übler, C Willott, J Witstok, S Baum, R Bhatawdekar, K Boyett, Z Chen, A de Graaff, M Florian, JM Helton, RE Hviding, Z Ji, N Kumari, J Lyu, E Nelson, L Sandles, A Saxena, KA Suess, F Sun, M Topping, IEB Wallace

MIGHTEE-H I: the first MeerKAT H I mass function from an untargeted interferometric survey

Monthly Notices of the Royal Astronomical Society Oxford University Press 522:4 (2023) 5308-5319

Authors:

Anastasia A Ponomareva, Matt J Jarvis, Hengxing Pan, Natasha Maddox, Michael G Jones, Bradley S Frank, Sambatriniaina HA Rajohnson, Wanga Mulaudzi, Martin Meyer, Elizabeth AK Adams, Maarten Baes, Kelley M Hess, Sushma Kurapati, Isabella Prandoni, Francesco Sinigaglia, Kristine Spekkens, Madalina Tudorache, Ian Heywood, Jordan D Collier, Srikrishna Sekhar

Abstract:

We present the first measurement of the H I mass function (HIMF) using data from MeerKAT, based on 276 direct detections from the MeerKAT International GigaHertz Tiered Extragalactic Exploration (MIGHTEE) Survey Early Science data covering a period of approximately a billion years (0 ≤ z ≤ 0.084). This is the first HIMF measured using interferometric data over non-group or cluster field, i.e. a deep blank field. We constrain the parameters of the Schechter function that describes the HIMF with two different methods: 1/Vmax and modified maximum likelihood (MML). We find a low-mass slope α=−1.29+0.37−0.26 , ‘knee’ mass log10(M∗/M⊙)=10.07+0.24−0.24 and normalization log10(ϕ∗/Mpc−3)=−2.34+0.32−0.36 (H0 = 67.4 km s−1 Mpc−1) for 1/Vmax , and α=−1.44+0.13−0.10 , ‘knee’ mass log10(M∗/M⊙)=10.22+0.10−0.13 and normalization log10(ϕ∗/Mpc−3)=−2.52+0.19−0.14 for MML. When using 1/Vmax we find both the low-mass slope and ‘knee’ mass to be consistent within 1σ with previous studies based on single-dish surveys. The cosmological mass density of H I is found to be slightly larger than previously reported: ΩHI=5.46+0.94−0.99×10−4h−167.4 from 1/Vmax and ΩHI=6.31+0.31−0.31×10−4h−167.4 from MML but consistent within the uncertainties. We find no evidence for evolution of the HIMF over the last billion years.

Spectroscopic confirmation of four metal-poor galaxies at z = 10.3–13.2

Nature Astronomy Springer Nature 7:5 (2023) 622-632

Authors:

Emma Curtis-Lake, Stefano Carniani, Alex Cameron, Stephane Charlot, Peter Jakobsen, Roberto Maiolino, Andrew Bunker, Joris Witstok, Renske Smit, Jacopo Chevallard, Chris Willott, Pierre Ferruit, Santiago Arribas, Nina Bonaventura, Mirko Curti, Francesco D’Eugenio, Marijn Franx, Giovanna Giardino, Tobias J Looser, Nora Lützgendorf, Michael V Maseda, Tim Rawle, Hans-Walter Rix, Bruno Rodríguez del Pino, Hannah Übler, Marco Sirianni, Alan Dressler, Eiichi Egami, Daniel J Eisenstein, Ryan Endsley, Kevin Hainline, Ryan Hausen, Benjamin D Johnson, Marcia Rieke, Brant Robertson, Irene Shivaei, Daniel P Stark, Sandro Tacchella, Christina C Williams, Christopher NA Willmer, Rachana Bhatawdekar, Rebecca Bowler, Kristan Boyett, Zuyi Chen, Anna de Graaff, Jakob M Helton, Raphael E Hviding, Gareth C Jones, Nimisha Kumari, Jianwei Lyu, Erica Nelson, Michele Perna, Lester Sandles, Aayush Saxena, Katherine A Suess, Fengwu Sun, Michael W Topping, Imaan EB Wallace, Lily Whitler

The LOFAR Two-metre Sky Survey: Deep Fields data release 1. V. Survey description, source classifications, and host galaxy properties

Monthly Notices of the Royal Astronomical Society Oxford University Press 523:2 (2023) 1729-1755

Authors:

Pn Best, R Kondapally, Wl Williams, Rk Cochrane, Kj Duncan, Cl Hale, P Haskell, K Małek, I McCheyne, Djb Smith, L Wang, A Botteon, M Bonato, M Bondi, G Calistro Rivera, F Gao, G Gürkan, Mj Hardcastle, Matthew J Jarvis, B Mingo, H Miraghaei, Lk Morabito, D Nisbet, I Prandoni, Hja Röttgering, J Sabater, T Shimwell, C Tasse, R van Weeren

Abstract:

Source classifications, stellar masses, and star-formation rates are presented for ≈80 000 radio sources from the first data release of the Low Frequency Array Two-metre Sky Survey (LoTSS) Deep Fields, which represents the widest deep radio survey ever undertaken. Using deep multi-wavelength data spanning from the ultraviolet to the far-infrared, spectral energy distribution (SED) fitting is carried out for all of the LoTSS Deep host galaxies using four different SED codes, two of which include modelling of the contributions from an active galactic nucleus (AGN). Comparing the results of the four codes, galaxies that host a radiative AGN are identified, and an optimized consensus estimate of the stellar mass and star-formation rate for each galaxy is derived. Those galaxies with an excess of radio emission over that expected from star formation are then identified, and the LoTSS Deep sources are divided into four classes: star-forming galaxies, radio-quiet AGN, and radio-loud high-excitation and low-excitation AGN. Ninety-five per cent of the sources can be reliably classified, of which more than two-thirds are star-forming galaxies, ranging from normal galaxies in the nearby Universe to highly-starbursting systems at z > 4. Star-forming galaxies become the dominant population below 150-MHz flux densities of ≈1 mJy, accounting for 90 per cent of sources at S_150MHz ∼ 100 μJy. Radio-quiet AGN comprise ≈10 per cent of the overall population. Results are compared against the predictions of the SKADS and T-RECS radio sky simulations, and improvements to the simulations are suggested.