Beecroft Institute for Particle Astrophysics and Cosmology

TOI-1338: TESS' First Transiting Circumbinary Planet

ASTRONOMICAL JOURNAL 159:6 (2020) ARTN 253

Authors:

Veselin B Kostov, Jerome A Orosz, Adina D Feinstein, William F Welsh, Wolf Cukier, Nader Haghighipour, Billy Quarles, David V Martin, Benjamin T Montet, Guillermo Torres, Amaury HMJ Triaud, Thomas Barclay, Patricia Boyd, Cesar Briceno, Andrew Collier Cameron, Alexandre CM Correia, Emily A Gilbert, Samuel Gill, Michael Gillon, Jacob Haqq-Misra, Coel Hellier, Courtney Dressing, Daniel C Fabrycky, Gabor Furesz, Jon Jenkins, Stephen R Kane, Ravi Kopparapu, Vedad Kunovac Hodzic, David W Latham, Nicholas Law, Alan M Levine, Gongjie Li, Chris Lintott, Jack J Lissauer, Andrew W Mann, Tsevi Mazeh, Rosemary Mardling, Pierre FL Maxted, Nora Eisner, Francesco Pepe, Joshua Pepper, Don Pollacco, Samuel N Quinn, Elisa V Quintana, Jason F Rowe, George Ricker, Mark E Rose, S Seager, Alexandre Santerne, Damien Segransan

Abstract:

© 2020. The American Astronomical Society. All rights reserved. We report the detection of the first circumbinary planet (CBP) found by Transiting Exoplanet Survey Satellite (TESS). The target, a known eclipsing binary, was observed in sectors 1 through 12 at 30 minute cadence and in sectors 4 through 12 at 2 minute cadence. It consists of two stars with masses of 1.1 M o˙ and 0.3 M o˙ on a slightly eccentric (0.16), 14.6 day orbit, producing prominent primary eclipses and shallow secondary eclipses. The planet has a radius of ∼6.9 R ⊕ and was observed to make three transits across the primary star of roughly equal depths (∼0.2%) but different durations-a common signature of transiting CBPs. Its orbit is nearly circular (e ≈ 0.09) with an orbital period of 95.2 days. The orbital planes of the binary and the planet are aligned to within ∼1°. To obtain a complete solution for the system, we combined the TESS photometry with existing ground-based radial-velocity observations in a numerical photometric-dynamical model. The system demonstrates the discovery potential of TESS for CBPs and provides further understanding of the formation and evolution of planets orbiting close binary stars.

The Horizon Run 5 Cosmological Hydrodynamic Simulation: Probing Galaxy Formation from Kilo- to Giga-parsec Scales

(2020)

Authors:

Jaehyun Lee, Jihye Shin, Owain N Snaith, Yonghwi Kim, C Gareth Few, Julien Devriendt, Yohan Dubois, Leah M Cox, Sungwook E Hong, Oh-Kyoung Kwon, Chan Park, Christophe Pichon, Juhan Kim, Brad K Gibson, Changbom Park

X-ray variability analysis of a large series of XMM–Newton +NuSTAR observations of NGC 3227

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 494:4 (2020) 5056-5074

Authors:

AP Lobban, TJ Turner, JN Reeves, V Braito, L Miller

The QUBIC instrument for CMB polarization measurements

Journal of Physics: Conference Series IOP Publishing 1548:1 (2020)

Authors:

L Mele, P Ade, Jg Alberro, Susanna Azzoni

Abstract:

Measurements of cosmic microwave background (CMB) polarization may reveal the presence of a background of gravitational waves produced during cosmic inflation, providing thus a test of inflationary models. The Q&U Bolometric Interferometer for Cosmology (QUBIC) is an experiment designed to measure the CMB polarization. It is based on the novel concept of bolometric interferometry, which combines the sensitivity of bolometric detectors with the properties of beam synthesis and control of calibration offered by interferometers. To modulate and extract the input polarized signal of the CMB, QUBIC exploits Stokes polarimetry based on a rotating half-wave plate (HWP). In this work, we illustrate the design of the QUBIC instrument, focusing on the polarization modulation system, and we present preliminary results of beam calibrations and the performance of the HWP rotator at 300 K.

How primordial magnetic fields shrink galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press 495:4 (2020) 4475-4495

Authors:

Sergio Martin-Alvarez, Adrianne Slyz, Julien Devriendt, Carlos Gomez-Guijarro

Abstract:

As one of the prime contributors to the interstellar medium energy budget, magnetic fields naturally play a part in shaping the evolution of galaxies. Galactic magnetic fields can originate from strong primordial magnetic fields provided these latter remain below current observational upper limits. To understand how such magnetic fields would affect the global morphological and dynamical properties of galaxies, we use a suite of high-resolution constrained transport magnetohydrodynamic cosmological zoom simulations where we vary the initial magnetic field strength and configuration along with the prescription for stellar feedback. We find that strong primordial magnetic fields delay the onset of star formation and drain the rotational support of the galaxy, diminishing the radial size of the galactic disc and driving a higher amount of gas towards the centre. This is also reflected in mock UVJ observations by an increase in the light profile concentration of the galaxy. We explore the possible mechanisms behind such a reduction in angular momentum, focusing on magnetic braking. Finally, noticing that the effects of primordial magnetic fields are amplified in the presence of stellar feedback, we briefly discuss whether the changes we measure would also be expected for galactic magnetic fields of non-primordial origin.