Astronomical instrumentation

Molecular cross-sections for high-resolution spectroscopy of super-Earths, warm Neptunes, and hot Jupiters

Monthly Notices of the Royal Astronomical Society Oxford University Press 495:1 (2020) 224-237

Authors:

Siddharth Gandhi, Matteo Brogi, Sergei N Yurchenko, Jonathan Tennyson, Phillip A Coles, Rebecca K Webb, Jayne L Birkby, Gloria Guilluy, George A Hawker, Nikku Madhusudhan, Aldo S Bonomo, Alessandro Sozzetti

Abstract:

High-resolution spectroscopy (HRS) has been used to detect a number of species in the atmospheres of hot Jupiters. Key to such detections is accurately and precisely modelled spectra for cross-correlation against the R ≳ 20 000 observations. There is a need for the latest generation of opacities which form the basis for high signal-to-noise detections using such spectra. In this study we present and make publicly available cross-sections for six molecular species, H2O, CO, HCN, CH4, NH3, and CO2 using the latest line lists most suitable for low- and high-resolution spectroscopy. We focus on the infrared (0.95–5 μm) and between 500 and 1500 K where these species have strong spectral signatures. We generate these cross-sections on a grid of pressures and temperatures typical for the photospheres of super-Earth, warm Neptunes, and hot Jupiters using the latest H2 and He pressure broadening. We highlight the most prominent infrared spectral features by modelling three representative exoplanets, GJ 1214 b, GJ 3470 b, and HD 189733 b, which encompass a wide range in temperature, mass, and radii. In addition, we verify the line lists for H2O, CO, and HCN with previous high-resolution observations of hot Jupiters. However, we are unable to detect CH4 with our new cross-sections from HRS observations of HD 102195 b. These high-accuracy opacities are critical for atmospheric detections with HRS and will be continually updated as new data become available.

Progress Report on the Large-Scale Polarization Explorer

JOURNAL OF LOW TEMPERATURE PHYSICS Springer Science and Business Media LLC 200:5-6 (2020) 374-383

Authors:

L Lamagna, G Addamo, Par Ade, C Baccigalupi, Am Baldini, Pm Battaglia, E Battistelli, A Bau, M Bersanelli, M Biasotti, C Boragno, A Boscaleri, B Caccianiga, S Caprioli, F Cavaliere, F Cei, Ka Cleary, F Columbro, G Coppi, A Coppolecchia, D Corsini, F Cuttaia, G D'Alessandro, P de Bernardis, G De Gasperis, M De Petris, F Del Torto, V Fafone, Z Farooqui, F Farsian, F Fontanelli, C Franceschet, Tc Gaier, F Gatti, R Genova-Santos, M Gervasi, T Ghigna, M Grassi, D Grosso, F Incardona, M Jones, P Kangaslahti, N Krachmalnicoff, R Mainini, D Maino, S Mandelli, M Maris, S Masi, S Matarrese, A May

Abstract:

© 2020, Springer Science+Business Media, LLC, part of Springer Nature. The large-scale polarization explorer (LSPE) is a cosmology program for the measurement of large-scale curl-like features (B-modes) in the polarization of the cosmic microwave background. Its goal is to constrain the background of inflationary gravity waves traveling through the universe at the time of matter-radiation decoupling. The two instruments of LSPE are meant to synergically operate by covering a large portion of the northern microwave sky. LSPE/STRIP is a coherent array of receivers planned to be operated from the Teide Observatory in Tenerife, for the control and characterization of the low-frequency polarized signals of galactic origin; LSPE/SWIPE is a balloon-borne bolometric polarimeter based on 330 large throughput multi-moded detectors, designed to measure the CMB polarization at 150 GHz and to monitor the polarized emission by galactic dust above 200 GHz. The combined performance and the expected level of systematics mitigation will allow LSPE to constrain primordial B-modes down to a tensor/scalar ratio of 10 - 2. We here report the status of the STRIP pre-commissioning phase and the progress in the characterization of the key subsystems of the SWIPE payload (namely the cryogenic polarization modulation unit and the multi-moded TES pixels) prior to receiver integration.

Molecular Cross Sections for High Resolution Spectroscopy of Super Earths, Warm Neptunes and Hot Jupiters

(2020)

Authors:

Siddharth Gandhi, Matteo Brogi, Sergei N Yurchenko, Jonathan Tennyson, Phillip A Coles, Rebecca K Webb, Jayne L Birkby, Gloria Guilluy, George A Hawker, Nikku Madhusudhan, Aldo S Bonomo, Alessandro Sozzetti

Survey of Gravitationally-lensed Objects in HSC Imaging (SuGOHI). VI. Crowdsourced lens finding with Space Warps

(2020)

Authors:

Alessandro Sonnenfeld, Aprajita Verma, Anupreeta More, Elisabeth Baeten, Christine Macmillan, Kenneth C Wong, James HH Chan, Anton T Jaelani, Chien-Hsiu Lee, Masamune Oguri, Cristian E Rusu, Marten Veldthuis, Laura Trouille, Philip J Marshall, Roger Hutchings, Campbell Allen, James O' Donnell, Claude Cornen, Christopher Davis, Adam McMaster, Chris Lintott, Grant Miller

Formation channels of slowly rotating early-type galaxies

Astronomy and Astrophysics EDP Sciences 635 (2020) A129

Authors:

Davor Krajnovic, Ugur Ural, Harald Kuntschner, Paul Goudfrooij, Michael Wolfe, Michele Cappellari, Roger Davies, Tim P de Zeeuw, Pierre-Alain Duc, Eric Emsellem, Arna Karick, Richard M McDermid, Simona Mei, Thorsten Naab

Abstract:

We study the evidence for a diversity of formation processes in early-type galaxies by presenting the first complete volume-limited sample of slow rotators with both integral-field kinematics from the ATLAS3D Project and high spatial resolution photometry from the Hubble Space Telescope. Analysing the nuclear surface brightness profiles of 12 newly imaged slow rotators, we classify their light profiles as core-less, and place an upper limit to the core size of about 10 pc. Considering the full magnitude and volume-limited ATLAS3D sample, we correlate the presence or lack of cores with stellar kinematics, including the proxy for the stellar angular momentum (λRe) and the velocity dispersion within one half-light radius (σe), stellar mass, stellar age, α-element abundance, and age and metallicity gradients. More than half of the slow rotators have core-less light profiles, and they are all less massive than 1011 M⊙. Core-less slow rotators show evidence for counter-rotating flattened structures, have steeper metallicity gradients, and a larger dispersion of gradient values (Δ[Z/H]¯ = −0.42 ± 0.18) than core slow rotators (Δ[Z/H]¯ = −0.23 ± 0.07). Our results suggest that core and core-less slow rotators have different assembly processes, where the former, as previously discussed, are the relics of massive dissipation-less merging in the presence of central supermassive black holes. Formation processes of core-less slow rotators are consistent with accretion of counter-rotating gas or gas-rich mergers of special orbital configurations, which lower the final net angular momentum of stars, but support star formation. We also highlight core fast rotators as galaxies that share properties of core slow rotators (i.e. cores, ages, σe, and population gradients) and core-less slow rotators (i.e. kinematics, λRe, mass, and larger spread in population gradients). Formation processes similar to those for core-less slow rotators can be invoked to explain the assembly of core fast rotators, with the distinction that these processes form or preserve cores.