On the viability of determining galaxy properties from observations I: Star formation rates and kinematics

Monthly Notices of the Royal Astronomical Society Oxford University Press 513:3 (2022) 3906-3924

Authors:

Kearn Grisdale, Laurence Hogan, Dimitra Rigopoulou, Niranjan Thatte, Miguel Pereira-Santaella, Julien Devriendt, Adrianne Slyz, Ismael García-Bernete, Yohan Dubois, Sukyoung K Yi, Katarina Kraljic

Abstract:

We explore how observations relate to the physical properties of the emitting galaxies by post-processing a pair of merging z ∼ 2 galaxies from the cosmological, hydrodynamical simulation NEWHORIZON, using LCARS (Light from Cloudy Added to RAMSES) to encode the physical properties of the simulated galaxy into H α emission line. By carrying out mock observations and analysis on these data cubes, we ascertain which physical properties of the galaxy will be recoverable with the HARMONI spectrograph on the European Extremely Large Telescope (ELT). We are able to estimate the galaxy’s star formation rate and dynamical mass to a reasonable degree of accuracy, with values within a factor of 1.81 and 1.38 of the true value. The kinematic structure of the galaxy is also recovered in mock observations. Furthermore, we are able to recover radial profiles of the velocity dispersion and are therefore able to calculate how the dynamical ratio varies as a function of distance from the galaxy centre. Finally, we show that when calculated on galaxy scales the dynamical ratio does not always provide a reliable measure of a galaxy’s stability against gravity or act as an indicator of a minor merger.

On the Viability of Determining Galaxy Properties from Observations I: Star Formation Rates and Kinematics

(2022)

Authors:

Kearn Grisdale, Laurence Hogan, Dimitra Rigopoulou, Niranjan Thatte, Miguel Pereira-Santaella, Julien Devriendt, Adrianne Slyz, Ismael García-Bernete, Yohan Dubois, Sukyoung K Yi, Katarina Kraljic

A new look at local ultraluminous infrared galaxies: the atlas and radiative transfer models of their complex physics

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 512:4 (2022) 5183-5213

Authors:

A Efstathiou, D Farrah, J Afonso, DL Clements, E González-Alfonso, M Lacy, S Oliver, V Papadopoulou Lesta, C Pearson, D Rigopoulou, M Rowan-Robinson, HWW Spoon, A Verma, L Wang

The KLEVER survey: nitrogen abundances at z ∼ 2 and probing the existence of a fundamental nitrogen relation

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 512:2 (2022) 2867-2889

Authors:

Connor Hayden-Pawson, Mirko Curti, Roberto Maiolino, Michele Cirasuolo, Francesco Belfiore, Michele Cappellari, Alice Concas, Giovanni Cresci, Fergus Cullen, Chiaki Kobayashi, Filippo Mannucci, Alessandro Marconi, Massimo Meneghetti, Amata Mercurio, Yingjie Peng, Mark Swinbank, Fiorenzo Vincenzo

Black Mirror: The impact of rotational broadening on the search for reflected light from 51 Pegasi b with high resolution spectroscopy

Astronomy & Astrophysics EDP Sciences 659 (2022) A121-A121

Authors:

EF Spring, JL Birkby, L Pino, R Alonso, S Hoyer, ME Young, PRT Coelho, D Nespral, M López-Morales

Abstract:

Abstract In the past decade the study of exoplanet atmospheres at high-spectral resolution, via transmission/emission spectroscopy and cross-correlation techniques for atomic/molecular mapping, has become a powerful and consolidated methodology. The current limitation is the signal-to-noise ratio that one can obtain during a planetary transit, which is in turn ultimately limited by telescope size. This limitation will be overcome by ANDES, an optical and near-infrared high-resolution spectrograph for the Extremely Large Telescope, which is currently in Phase B development. ANDES will be a powerful transformational instrument for exoplanet science. It will enable the study of giant planet atmospheres, allowing not only an exquisite determination of atmospheric composition, but also the study of isotopic compositions, dynamics and weather patterns, mapping the planetary atmospheres and probing atmospheric formation and evolution models. The unprecedented angular resolution of ANDES, will also allow us to explore the initial conditions in which planets form in proto-planetary disks. The main science case of ANDES, however, is the study of small, rocky exoplanet atmospheres, including the potential for biomarker detections, and the ability to reach this science case is driving its instrumental design. Here we discuss our simulations and the observing strategies to achieve this specific science goal. Since ANDES will be operational at the same time as NASA’s JWST and ESA’s ARIEL missions, it will provide enormous synergies in the characterization of planetary atmospheres at high and low spectral resolution. Moreover, ANDES will be able to probe for the first time the atmospheres of several giant and small planets in reflected light. In particular, we show how ANDES will be able to unlock the reflected light atmospheric signal of a golden sample of nearby non-transiting habitable zone earth-sized planets within a few tenths of nights, a scientific objective that no other currently approved astronomical facility will be able to reach.