Cosmology

MIGHTEE - H I. The relation between the H I gas in galaxies and the cosmic web

Monthly Notices of the Royal Astronomical Society Oxford University Press 513:2 (2022) 2168-2177

Authors:

Madalina N Tudorache, Mj Jarvis, I Heywood, Aa Ponomareva, N Maddox, Bs Frank, Nj Adams, Raa Bowler, Ih Whittam, M Baes, H Pan, Sha Rajohnson, F Sinigaglia, K Spekkens

Abstract:

We study the 3D axis of rotation (3D spin) of 77 Hi galaxies from the MIGHTEE-Hi Early Science observations, and its relation to the filaments of the cosmic web. For this Hi-selected sample, the alignment between the spin axis and the closest filament (|cos ψ|) is higher for galaxies closer to the filaments, with 〈|cos ψ|〉 = 0.66 ± 0.04 for galaxies <5 Mpc from their closest filament compared to 〈|cos ψ|〉 = 0.37 ± 0.08 for galaxies at 5 < d < 10 Mpc. We find that galaxies with a low Hi-to-stellar mass ratio (log10(MHi/M∗) < 0.11) are more aligned with their closest filaments, with 〈|cos ψ|〉 = 0.58 ± 0.04; whilst galaxies with (log10(MHi/M∗) > 0.11) tend to be mis-aligned, with 〈|cos ψ|〉 = 0.44 ± 0.04. We find tentative evidence that the spin axis of Hi-selected galaxies tend to be aligned with associated filaments (d < 10 Mpc), but this depends on the gas fractions. Galaxies that have accumulated more stellar mass compared to their gas mass tend towards stronger alignment. Our results suggest that those galaxies that have accrued high gas fraction with respect to their stellar mass may have had their spin axis alignment with the filament disrupted by a recent gas-rich merger, whereas the spin vector for those galaxies in which the neutral gas has not been strongly replenished through a recent merger tend to orientate towards alignment with the filament. We also investigate the spin transition between galaxies with a high Hi content and a low Hi content at a threshold of MHI ≈ 109.5 M⊙ found in simulations; however, we find no evidence for such a transition with the current data.

ShapePipe: a new shape measurement pipeline and weak-lensing application to UNIONS/CFIS data

ArXiv 2204.04798 (2022)

Authors:

Axel Guinot, Martin Kilbinger, Samuel Farrens, Austin Peel, Arnau Pujol, Morgan Schmitz, Jean-Luc Starck, Thomas Erben, Raphael Gavazzi, Stephen Gwyn, Michael J Hudson, Hendrik Hiledebrandt, Tobias Liaudat, Lance Miller, Isaac Spitzer, Ludovic Van Waerbeke, Jean-Charles Cuillandre, Sébastien Fabbro, Alan McConnachie

Simulating jellyfish galaxies: a case study for a gas-rich dwarf galaxy

The Astrophysical Journal IOP Publishing 928:2 (2022) 144

Authors:

Jaehyun Lee, Taysun Kimm, Jeremy Blaizot, Harley Katz, Wonki Lee, Yun-Kyeong Sheen, Julien Devriendt, Adrianne Slyz

Abstract:

We investigate the formation of jellyfish galaxies using radiation-hydrodynamic simulations of gas-rich dwarf galaxies with a multiphase interstellar medium (ISM). We find that the ram-pressure-stripped (RPS) ISM is the dominant source of molecular clumps in the near wake within 10 kpc from the galactic plane, while in situ formation is the major channel for dense gas in the distant tail of the gas-rich galaxy. Only 20% of the molecular clumps in the near wake originate from the intracluster medium (ICM); however, the fraction reaches 50% in the clumps located at 80 kpc from the galactic center since the cooling time of the RPS gas tends to be short owing to the ISM–ICM mixing (≲10 Myr). The tail region exhibits a star formation rate of 0.001–0.01 M⊙ yr−1, and most of the tail stars are born in the stripped wake within 10 kpc from the galactic plane. These stars induce bright Hα blobs in the tail, while Hα tails fainter than 6 × 1038 erg s−1 kpc−2 are mostly formed via collisional radiation and heating due to mixing. We also find that the stripped tails have intermediate X-ray-to-Hα surface brightness ratios (1.5 ≲ FX/FHα ≲ 20), compared to the ISM (≲1.5) or pure ICM (≫20). Our results suggest that jellyfish features emerge when the ISM from gas-rich galaxies is stripped by strong ram pressure, mixes with the ICM, and enhances the cooling in the tail.

QUBIC I: Overview and science program

Journal of Cosmology and Astroparticle Physics IOP Publishing 2022:04 (2022) 034

Authors:

The QUBIC collaboration, J-Ch Hamilton, L Mousset, ES Battistelli, P de Bernardis, M-A Bigot-Sazy, P Chanial, R Charlassier, G D'Alessandro, M De Petris, MM Gamboa Lerena, L Grandsire, S Landau, S Mandelli, S Marnieros, S Masi, A Mennella, C O'Sullivan, M Piat, G Ricciardi, CG Scóccola, M Stolpovskiy, A Tartari, SA Torchinsky, F Voisin, M Zannoni, P Ade, JG Alberro, A Almela, G Amico, LH Arnaldi, D Auguste, J Aumont, S Azzoni, S Banfi, A Baù, B Bélier, D Bennett, L Bergé, J-Ph Bernard, M Bersanelli, J Bonaparte, J Bonis, E Bunn, D Burke, D Buzi, F Cavaliere, C Chapron, AC Cobos Cerutti, F Columbro, A Coppolecchia, G De Gasperis, M De Leo, S Dheilly, C Duca, L Dumoulin, A Etchegoyen, A Fasciszewski, LP Ferreyro, D Fracchia, C Franceschet, KM Ganga, B García, ME García Redondo, M Gaspard, D Gayer, M Gervasi, M Giard, V Gilles, Y Giraud-Heraud, M Gómez Berisso, M González, M Gradziel, MR Hampel, D Harari, S Henrot-Versillé, F Incardona, E Jules, J Kaplan, C Kristukat, L Lamagna, S Loucatos, T Louis, B Maffei, W Marty, A Mattei, A May, M McCulloch, L Mele, D Melo, L Montier, LM Mundo, JA Murphy, JD Murphy, F Nati, E Olivieri, C Oriol, A Paiella, F Pajot, A Passerini, H Pastoriza, A Pelosi, C Perbost, M Perciballi, F Pezzotta, F Piacentini, L Piccirillo, G Pisano, M Platino, G Polenta, D Prêle, R Puddu, D Rambaud, E Rasztocky, P Ringegni, GE Romero, JM Salum, A Schillaci, S Scully, S Spinelli, G Stankowiak, AD Supanitsky, J-P Thermeau, P Timbie, M Tomasi, C Tucker, G Tucker, D Viganò, N Vittorio, F Wicek, M Wright, A Zullo

QUBIC II: Spectral polarimetry with bolometric interferometry

Journal of Cosmology and Astroparticle Physics IOP Publishing 2022:04 (2022) 035

Authors:

The QUBIC collaboration, L Mousset, MM Gamboa Lerena, ES Battistelli, P de Bernardis, P Chanial, G D'Alessandro, G Dashyan, M De Petris, L Grandsire, J-Ch Hamilton, F Incardona, S Landau, S Marnieros, S Masi, A Mennella, C O'Sullivan, M Piat, G Ricciardi, CG Scóccola, M Stolpovskiy, A Tartari, J-P Thermeau, SA Torchinsky, F Voisin, M Zannoni, P Ade, JG Alberro, A Almela, G Amico, LH Arnaldi, D Auguste, J Aumont, S Azzoni, S Banfi, A Baù, B Bélier, D Bennett, L Bergé, J-Ph Bernard, M Bersanelli, M-A Bigot-Sazy, J Bonaparte, J Bonis, E Bunn, D Burke, D Buzi, F Cavaliere, C Chapron, R Charlassier, AC Cobos Cerutti, F Columbro, A Coppolecchia, G De Gasperis, M De Leo, S Dheilly, C Duca, L Dumoulin, A Etchegoyen, A Fasciszewski, LP Ferreyro, D Fracchia, C Franceschet, KM Ganga, B García, ME García Redondo, M Gaspard, D Gayer, M Gervasi, M Giard, V Gilles, Y Giraud-Heraud, M Gómez Berisso, M González, M Gradziel, MR Hampel, D Harari, S Henrot-Versillé, E Jules, J Kaplan, C Kristukat, L Lamagna, S Loucatos, T Louis, B Maffei, S Mandelli, W Marty, A Mattei, A May, M McCulloch, L Mele, D Melo, L Montier, LM Mundo, JA Murphy, JD Murphy, F Nati, E Olivieri, C Oriol, A Paiella, F Pajot, A Passerini, H Pastoriza, A Pelosi, C Perbost, M Perciballi, F Pezzotta, F Piacentini, L Piccirillo, G Pisano, M Platino, G Polenta, D Prêle, R Puddu, D Rambaud, E Rasztocky, P Ringegni, GE Romero, JM Salum, A Schillaci, S Scully, S Spinelli, G Stankowiak, AD Supanitsky, P Timbie, M Tomasi, C Tucker, G Tucker, D Viganò, N Vittorio, F Wicek, M Wright, A Zullo