Hintze Centre for Astrophysical Surveys

AT2023vfi/GRB230307A JWST spectral data set

Abstract:

This data set contains the two JWST NIRSpec spectra presented by Gillanders & Smartt (2025). These spectra have been carefully extracted and flux-calibrated to contemporaneous photometry. For full details of the reduction, see Gillanders & Smartt (2025) (linked below). If you utilise these spectra, you must cite Levan et al. (2024) in addition to Gillanders & Smartt (2025). Link to articles: Gillanders & Smartt (2025): https://academic.oup.com/mnras/advance-article/doi/10.1093/mnras/staf287/8019796 Levan et al., (2024): https://www.nature.com/articles/s41586-023-06759-1

Comparing Galaxy Clustering in Horizon-AGN Simulated Lightcone Mocks and VIDEO Observations

Authors:

P Hatfield, C Laigle, M Jarvis, JULIEN Devriendt, I Davidzon, O Ilbert, C Pichon, Y Dubois

Abstract:

Hydrodynamical cosmological simulations have recently made great advances in reproducing galaxy mass assembly over cosmic time - as often quantified from the comparison of their predicted stellar mass functions to observed stellar mass functions from data. In this paper we compare the clustering of galaxies from the hydrodynamical cosmological simulated lightcone Horizon-AGN, to clustering measurements from the VIDEO survey observations. Using mocks built from a VIDEO-like photometry, we first explore the bias introduced into clustering measurements by using stellar masses and redshifts derived from SED-fitting, rather than the intrinsic values. The propagation of redshift and mass statistical and systematic uncertainties in the clustering measurements causes us to underestimate the clustering amplitude. We find then that clustering and halo occupation distribution (HOD) modelling results are qualitatively similar in Horizon-AGN and VIDEO. However at low stellar masses Horizon-AGN underestimates the observed clustering by up to a factor of ~3, reflecting the known excess stellar mass to halo mass ratio for Horizon-AGN low mass haloes, already discussed in previous works. This reinforces the need for stronger regulation of star formation in low mass haloes in the simulation. Finally, the comparison of the stellar mass to halo mass ratio in the simulated catalogue, inferred from angular clustering, to that directly measured from the simulation, validates HOD modelling of clustering as a probe of the galaxy-halo connection.

Dynamical Modeling of SAURON Galaxies

Carnegie Observatories Centennial Symposium. 1. Coevolution of Black Holes and Galaxies

Authors:

M Cappellari, RCE van den Bosch, EK Verolme, R Bacon, M Bureau, Y Copin, RL Davies, E Emsellem, D Krajnovic, H Kuntschner, R McDermid, BW Miller, RF Peletier, PT de Zeeuw

Abstract:

We describe our program for the dynamical modeling of early-type galaxies observed with the panoramic integral-field spectrograph SAURON. We are using Schwarzschild's numerical orbit superposition method to reproduce in detail all kinematical and photometric observables, and recover the intrinsic orbital structure of the galaxies. Since catastrophes are the most prominent features in the orbital observables, two-dimensional kinematical coverage is essential to constrain the dynamical models.

Dynamical modeling of SAURON galaxies

Proceedings of IUTAM Symposia and Summer Schools IUTAM 3

Authors:

Michele Cappellari, RCEVD Bosch, EK Verolme, R Bacon, Martin Bureau, Y Copin, RL Davies, E Emsellem, D Krajnovic, H Kuntschner, R McDermid, BW Miller, RF Peletier, PTD Zeeuw

Abstract:

We describe our program for the dynamical modeling of early-type galaxies observed with the panoramic integral-field spectrograph SAURON. We are using Schwarzschild's numerical orbit superposition method to reproduce in detail all kinematical and photometric observables, and recover the intrinsic orbital structure of the galaxies. Since catastrophes are the most prominent features in the orbital observables, two-dimensional kinematical coverage is essential to constrain the dynamical models.

JWST detection of heavy neutron capture elements in a compact object merger

Authors:

Andrew Levan, Benjamin Gompertz, Om Sharan Salafia, Mattia Bulla, Eric Burns, Kenta Hotokezaka, Luca Izzo, Gavin Lamb, Daniele Malesani, Samantha Oates, Maria Ravasio, Alicia Rouco Escorial, Benjamin Schneider, Nikhil Sarin, Steve Schulze, Nial Tanvir, Kendall Ackley, Gemma Anderson, Gabriel Brammer, Lise Christensen, Vikram Dhillon, Phil Evans, Michael Fausnaugh, Wen-fai Fong, Andrew Fruchter, Chris Fryer, Johan Fynbo, Nicola Gaspari, Kasper Heintz, Jens Hjorth, Jamie Kennea, Mark Kennedy, Tanmoy Laskar, Giorgos Leloudas, Ilya Mandel, Antonio Martín-Carrillo, Brian Metzger, Matt Nicholl, Anya Nugent, Jesse Palmerio, Giovanna Pugilese, Jillian Rastinejad, Lauren Rhodes, Andrea Rossi, Stephen Smartt, Heloise Stevance, Aaron Tohuvavohu, Alexander van der Horst, Susanna Vergani, Darach Watson, Thomas Barclay, Kornpob Bhirombhakdi, Elme Breedt, Alice Breeveld, Alex Brown, Sergio Campana, Paolo D'Avanzo, Valerio D'Elia, Massimiliano De Pasquale, Martin Dyer, Duncan Galloway, James Garbutt, Matthew Green, Dieter Hartmann, Pall Jakobsson, Paul Kerry, Danial Langeroodi, James Leung, Stuart Littlefair, James Munday, Paul O'Brien, Steven Parsons, Ingrid Pelisoli, Dave Sahman, Ruben Salvaterra, Gianpiero Tagliaferri, Christina Thöne, Antonio de Ugarte Postigo, Boris Sbarufatti, Ashley Chrimes, Danny Steeghs, David Kann