Rubin-LSST

The Simons Observatory: Combining cross-spectral foreground cleaning with multitracer $B$-mode delensing for improved constraints on inflation

(2024)

Authors:

Emilie Hertig, Kevin Wolz, Toshiya Namikawa, Antón Baleato Lizancos, Susanna Azzoni, Irene Abril-Cabezas, David Alonso, Carlo Baccigalupi, Erminia Calabrese, Anthony Challinor, Josquin Errard, Giulio Fabbian, Carlos Hervías-Caimapo, Baptiste Jost, Nicoletta Krachmalnicoff, Anto I Lonappan, Magdy Morshed, Luca Pagano, Blake Sherwin

Anti-Black Racism Workshop during the Vera C. Rubin Observatory Virtual 2021 Project and Community Workshop

Chapter in An Astronomical Inclusion Revolution, IOP Publishing (2024) 7-1-7-12

Authors:

Andrés A Plazas Malagón, Federica Bianco, Ranpal Gill, Robert D Blum, Rosaria Sara Bonito, Wil O’Mullane, Alsyha Shugart, Rachel Street, Aprajita Verma

Planet Hunters TESS. V. A Planetary System Around a Binary Star, Including a Mini-Neptune in the Habitable Zone

Astronomical Journal IOP Publishing 167:5 (2024) 241

Authors:

Nora L Eisner, Samuel K Grunblatt, Oscar Barragán, Thea H Faridani, Chris Lintott, Suzanne Aigrain, Cole Johnston, Ian R Mason, Keivan G Stassun, Megan Bedell, Andrew W Boyle, David R Ciardi, Catherine A Clark, Guillaume Hebrard, David W Hogg, Steve B Howell, Baptiste Klein, Joe Llama, Joshua N Winn, Lily L Zhao, Joseph M Akana Murphy, Corey Beard, Casey L Brinkman, Ashley Chontos, Safaa Alhassan, Daval J Amratlal, Lais I Antonel, Simon LS Bentzen, Milton KD Bosch, David Bundy, Itayi Chitsiga, Jérôme F Delaunay, Xavier Doisy, Richard Ferstenou

Abstract:

We report on the discovery and validation of a transiting long-period mini-Neptune orbiting a bright (V = 9.0 mag) G dwarf (TOI 4633; R = 1.05 R ⊙, M = 1.10 M ⊙). The planet was identified in data from the Transiting Exoplanet Survey Satellite by citizen scientists taking part in the Planet Hunters TESS project. Modelling of the transit events yields an orbital period of 271.9445 ± 0.0040 days and radius of 3.2 ± 0.20 R ⊕. The Earth-like orbital period and an incident flux of 1.56−0.16+0.20 F ⊕ places it in the optimistic habitable zone around the star. Doppler spectroscopy of the system allowed us to place an upper mass limit on the transiting planet and revealed a non-transiting planet candidate in the system with a period of 34.15 ± 0.15 days. Furthermore, the combination of archival data dating back to 1905 with new high angular resolution imaging revealed a stellar companion orbiting the primary star with an orbital period of around 230 yr and an eccentricity of about 0.9. The long period of the transiting planet, combined with the high eccentricity and close approach of the companion star makes this a valuable system for testing the formation and stability of planets in binary systems.

The Extremely Metal-Poor SN 2023ufx: A Local Analog to High-Redshift Type II Supernovae

(2024)

Authors:

Michael A Tucker, Jason Hinkle, Charlotte R Angus, Katie Auchettl, Willem B Hoogendam, Benjamin Shappee, Christopher S Kochanek, Chris Ashall, Thomas de Boer, Kenneth C Chambers, Dhvanil D Desai, Aaron Do, Michael D Fulton, Hua Gao, Joanna Herman, Mark Huber, Chris Lidman, Chien-Cheng Lin, Thomas B Lowe, Eugene A Magnier, Bailey Martin, Paloma Minguez, Matt Nicholl, Miika Pursiainen, SJ Smartt, Ken W Smith, Shubham Srivastav, Brad E Tucker, Richard J Wainscoat

Extragalactic Magnetism with SOFIA (SALSA Legacy Program). VII. A Tomographic View of Far-infrared and Radio Polarimetric Observations through MHD Simulations of Galaxies

The Astrophysical Journal American Astronomical Society 966:1 (2024) 43

Authors:

Sergio Martin-Alvarez, Enrique Lopez-Rodriguez, Tara Dacunha, Susan E Clark, Alejandro S Borlaff, Rainer Beck, Francisco Rodríguez Montero, Seoyoung L Jung, Julien Devriendt, Adrianne Slyz, Julia Christine Roman-Duval, Evangelia Ntormousi, Mehrnoosh Tahani, Kandaswamy Subramanian, Daniel A Dale, Pamela M Marcum, Konstantinos Tassis, Ignacio del Moral-Castro, Le Ngoc Tram, Matt J Jarvis

Abstract:

The structure of magnetic fields in galaxies remains poorly constrained, despite the importance of magnetism in the evolution of galaxies. Radio synchrotron and far-infrared (FIR) polarization and polarimetric observations are the best methods to measure galactic scale properties of magnetic fields in galaxies beyond the Milky Way. We use synthetic polarimetric observations of a simulated galaxy to identify and quantify the regions, scales, and interstellar medium (ISM) phases probed at FIR and radio wavelengths. Our studied suite of magnetohydrodynamical cosmological zoom-in simulations features high-resolutions (10 pc full-cell size) and multiple magnetization models. Our synthetic observations have a striking resemblance to those of observed galaxies. We find that the total and polarized radio emission extends to approximately double the altitude above the galactic disk (half-intensity disk thickness of h I radio ∼ h PI radio = 0.23 ± 0.03 kpc) relative to the total FIR and polarized emission that are concentrated in the disk midplane (h I FIR ∼ h PI FIR = 0.11 ± 0.01 kpc). Radio emission traces magnetic fields at scales of ≳300 pc, whereas FIR emission probes magnetic fields at the smallest scales of our simulations. These scales are comparable to our spatial resolution and well below the spatial resolution (<300 pc) of existing FIR polarimetric measurements. Finally, we confirm that synchrotron emission traces a combination of the warm neutral and cold neutral gas phases, whereas FIR emission follows the densest gas in the cold neutral phase in the simulation. These results are independent of the ISM magnetic field strength. The complementarity we measure between radio and FIR wavelengths motivates future multiwavelength polarimetric observations to advance our knowledge of extragalactic magnetism.