Hintze Centre for Astrophysical Surveys

Galaxy Zoo: kinematics of strongly and weakly barred galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press 521:2 (2023) 1775-1793

Authors:

Tobias Géron, Rebecca J Smethurst, Chris Lintott, Sandor Kruk, Karen L Masters, Brooke Simmons, Kameswara Bharadwaj Mantha, Mike Walmsley, L Garma-Oehmichen, Niv Drory, Richard R Lane

Abstract:

We study the bar pattern speeds and corotation radii of 225 barred galaxies, using integral field unit data from MaNGA and the Tremaine–Weinberg method. Our sample, which is divided between strongly and weakly barred galaxies identified via Galaxy Zoo, is the largest that this method has been applied to. We find lower pattern speeds for strongly barred galaxies than for weakly barred galaxies. As simulations show that the pattern speed decreases as the bar exchanges angular momentum with its host, these results suggest that strong bars are more evolved than weak bars. Interestingly, the corotation radius is not different between weakly and strongly barred galaxies, despite being proportional to bar length. We also find that the corotation radius is significantly different between quenching and star-forming galaxies. Additionally, we find that strongly barred galaxies have significantly lower values for R, the ratio between the corotation radius and the bar radius, than weakly barred galaxies, despite a big overlap in both distributions. This ratio classifies bars into ultrafast bars (R < 1.0; 11 per cent of our sample), fast bars (1.0 < R < 1.4; 27 per cent), and slow bars (R > 1.4; 62 per cent). Simulations show that R is correlated with the bar formation mechanism, so our results suggest that strong bars are more likely to be formed by different mechanisms than weak bars. Finally, we find a lower fraction of ultrafast bars than most other studies, which decreases the recently claimed tension with Lambda cold dark matter. However, the median value of R is still lower than what is predicted by simulations.

TDCOSMO

Astronomy & Astrophysics EDP Sciences 672 (2023) A20-A20

Authors:

P Mozumdar, CD Fassnacht, T Treu, C Spiniello, AJ Shajib

Abstract:

We have measured the redshifts and single-aperture velocity dispersions of eight lens galaxies using the data collected by the Echellette Spectrograph and Imager (ESI) and Low Resolution Imaging Spectrometer (LRIS) at W.M. Keck observatory on different observing nights spread over three years (2018-2020). These results, combined with other ancillary data, such as high-resolution images of the lens systems, and time delays, are necessary to increase the sample size of the quasar-galaxy lens systems for which the Hubble constant can be measured, using the time-delay strong lensing method, hence increasing the precision of its inference. Typically, the 2D spectra of the quasar-galaxy lens systems get spatially blended due to seeing by ground-based observations. As a result, the extracted lensing galaxy (deflector) spectra become significantly contaminated by quasar light, which affects the ability to extract meaningful information about the deflector. To account for spatial blending and extract less contaminated and higher signal-to-noise ratio (S/N) 1D spectra of the deflectors, a forward modeling method has been implemented. From the extracted spectra, we have measured redshifts using prominent absorption lines and single aperture velocity dispersions using the penalized pixel fitting code pPXF. In this paper, we report the redshifts and single aperture velocity dispersions of eight lens galaxies - J0147+4630, B0445+123, B0631+519, J0659+1629, J0818-2613, J0924+0219, J1433+6007, and J1817+2729. Among these systems, six do not have previously measured velocity dispersions; for the other two, our measurements are consistent with previously reported values. Additionally, we have measured the previously unknown redshifts of the deflectors in J0818-2613 and J1817+2729 to be $0.866 \pm 0.002$ and $0.408 \pm 0.002$, respectively.Comment: 13 pages, 6 figures, 3 tables; accepted in A&

A structured jet explains the extreme GRB 221009A

(2023)

Authors:

B O'Connor, E Troja, G Ryan, P Beniamini, H van Eerten, J Granot, S Dichiara, R Ricci, V Lipunov, JH Gillanders, R Gill, M Moss, S Anand, I Andreoni, RL Becerra, DAH Buckley, NR Butler, SB Cenko, A Chasovnikov, J Durbak, C Francile, E Hammerstein, AJ van der Horst, M Kasliwal, C Kouveliotou, AS Kutyrev, WH Lee, G Srinivasaragavan, V Topolev, AM Watson, YH Yang, K Zhirkov

Gravitationally lensed quasars in Gaia – IV. 150 new lenses, quasar pairs, and projected quasars

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 520:3 (2023) 3305-3328

Authors:

C Lemon, T Anguita, MW Auger-Williams, F Courbin, A Galan, R McMahon, F Neira, M Oguri, P Schechter, A Shajib, T Treu, A Agnello, C Spiniello

INSPIRE: INvestigating Stellar Population In RElics

Astronomy & Astrophysics EDP Sciences 672 (2023) A17-A17

Authors:

G D’Ago, C Spiniello, L Coccato, C Tortora, F La Barbera, M Arnaboldi, D Bevacqua, A Ferré-Mateu, A Gallazzi, J Hartke, LK Hunt, I Martín-Navarro, NR Napolitano, C Pulsoni, M Radovich, P Saracco, D Scognamiglio, S Zibetti

Abstract:

Context. The project called INvestigating Stellar Population In RElics (INSPIRE) is based on VLT/X-shooter data from the homonymous on-going ESO Large Program. It targets 52 ultra-compact massive galaxies at 0.1 < z < 0.5 with the goal of constraining their kinematics and stellar population properties in great detail and of analysing their relic nature. Aims. This is the second INSPIRE data release (DR2), comprising 21 new systems with observations completed before March 2022. For each system, we release four one-dimensional (1D) spectra to the ESO Science Archive, one spectrum for each arm of the X-Shooter spectrograph. They are at their original resolution. We also release a combined and smoothed spectrum with a full width at half maximum resolution of 2.51 Å. In this paper, we focus on the line-of-sight velocity distribution, measuring integrated stellar velocity dispersions from the spectra, and assessing their robustness and the associated uncertainties. Methods. For each of the 21 new systems, we systematically investigated the effect of the parameters and set-ups of the full spectral fitting on the stellar velocity dispersion (σ) measurements. In particular, we tested how σ changes when several parameters of the fit as well as the resolution and spectral coverage of the input spectra are varied. Results. We found that the effect that causes the largest systematic uncertainties on σ is the wavelength range used for the fit, especially for spectra with a lower signal-to-noise ratio (S/N ≤ 30). When using blue wavelengths (UVB arm) one generally underestimates the velocity dispersion (by ~15 km s−1). The values obtained from the near-IR (NIR) arm present a larger scatter because the quality of the spectra is lower. We finally compared our results with those in literature, finding a very good agreement overall. Conclusions. Joining results obtained in DR1 with those presented here, INSPIRE contains 40 ultra-compact massive galaxies, corresponding to 75% of the whole survey. By plotting these systems in a stellar mass-velocity dispersion diagram, we identify at least four highly reliable relic candidates among the new systems. Their velocity dispersion is larger than that of normal-sized galaxies of similar stellar mass.