Astronomical instrumentation

The Roasting Marshmallows Program with IGRINS on Gemini South I: Composition and Climate of the Ultrahot Jupiter WASP-18 b

The Astronomical Journal American Astronomical Society 165:3 (2023) 91

Authors:

Matteo Brogi, Vanessa Emeka-Okafor, Michael R Line, Siddharth Gandhi, Lorenzo Pino, Eliza M-R Kempton, Emily Rauscher, Vivien Parmentier, Jacob L Bean, Gregory N Mace, Nicolas B Cowan, Evgenya Shkolnik, Joost P Wardenier, Megan Mansfield, Luis Welbanks, Peter Smith, Jonathan J Fortney, Jayne L Birkby, Joseph A Zalesky, Lisa Dang, Jennifer Patience, Jean-Michel Désert

Measuring the variability of directly imaged exoplanets using vector Apodizing Phase Plates combined with ground-based differential spectrophotometry

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 520:3 (2023) 4235-4257

Authors:

Ben J Sutlieff, Jayne L Birkby, Jordan M Stone, David S Doelman, Matthew A Kenworthy, Vatsal Panwar, Alexander J Bohn, Steve Ertel, Frans Snik, Charles E Woodward, Andrew J Skemer, Jarron M Leisenring, Klaus G Strassmeier, David Charbonneau

WEAVE-StePS. A stellar population survey using WEAVE at WHT

(2023)

Authors:

A Iovino, BM Poggianti, A Mercurio, M Longhetti, M Bolzonella, G Busarello, M Gullieuszik, F LaBarbera, P Merluzzi, L Morelli, C Tortora, D Vergani, S Zibetti, CP Haines, L Costantin, FR Ditrani, L Pozzetti, J Angthopo, M Balcells, S Bardelli, CR Benn, M Bianconi, LP Cassarà, EM Corsini, O Cucciati, G Dalton, A Ferré-Mateu, M Fossati, A Gallazzi, R García-Benito, B Granett, RM González Delgado, A Ikhsanova, E Iodice, S Jin, JH Knapen, S McGee, A Moretti, DNA Murphy, L Peralta de Arriba, A Pizzella, P Sánchez-Blázquez, C Spiniello, M Talia, S Trager, A Vazdekis, B Vulcani

Starlight-polarization-based tomography of the magnetized ISM: P ASIPHAE - s line-of-sight inversion method

Astronomy and Astrophysics 670 (2023)

Authors:

V Pelgrims, GV Panopoulou, K Tassis, V Pavlidou, A Basyrov, D Blinov, E Gjerlw, S Kiehlmann, N Mandarakas, A Papadaki, R Skalidis, A Tsouros, RM Anche, HK Eriksen, T Ghosh, JA Kypriotakis, S Maharana, E Ntormousi, TJ Pearson, SB Potter, AN Ramaprakash, ACS Readhead, IK Wehus

Abstract:

We present the first Bayesian method for tomographic decomposition of the plane-of-sky orientation of the magnetic field with the use of stellar polarimetry and distance. This standalone tomographic inversion method presents an important step forward in reconstructing the magnetized interstellar medium (ISM) in three dimensions within dusty regions. We develop a model in which the polarization signal from the magnetized and dusty ISM is described by thin layers at various distances, a working assumption which should be satisfied in small-angular circular apertures. Our modeling makes it possible to infer the mean polarization (amplitude and orientation) induced by individual dusty clouds and to account for the turbulence-induced scatter in a generic way. We present a likelihood function that explicitly accounts for uncertainties in polarization and parallax. We develop a framework for reconstructing the magnetized ISM through the maximization of the log-likelihood using a nested sampling method. We test our Bayesian inversion method on mock data, representative of the high Galactic latitude sky, taking into account realistic uncertainties from Gaia and as expected for the optical polarization survey PASIPHAE according to the currently planned observing strategy. We demonstrate that our method is effective at recovering the cloud properties as soon as the polarization induced by a cloud to its background stars is higher than -0.1% for the adopted survey exposure time and level of systematic uncertainty. The larger the induced polarization is, the better the method s performance, and the lower the number of required stars. Our method makes it possible to recover not only the mean polarization properties but also to characterize the intrinsic scatter, thus creating new ways to characterize ISM turbulence and the magnetic field strength. Finally, we apply our method to an existing data set of starlight polarization with known line-of-sight decomposition, demonstrating agreement with previous results and an improved quantification of uncertainties in cloud properties.

Demonstrating 24-hour continuous vertical monitoring of atmospheric optical turbulence.

Optics express 31:4 (2023) 6730-6740

Authors:

Ryan Griffiths, James Osborn, Ollie Farley, Tim Butterley, Matthew J Townson, Richard Wilson

Abstract:

We report what is believed to be the first example of fully continuous, 24-hour vertical monitoring of atmospheric optical turbulence. This is achieved using a novel instrument, the 24-hour Shack-Hartmann Image Motion Monitor (24hSHIMM). Optical turbulence is a fundamental limitation for applications such as free-space optical communications, where it limits the achievable bandwidth, and ground-based optical astronomy, restricting the observational precision. Knowledge of the turbulence enables us to select the best sites, design optical instrumentation and optimise the operation of ground-based optical systems. The 24hSHIMM estimates the vertical optical turbulence coherence length, time, angle and Rytov variance from the measurement of a four-layer vertical turbulence profile and a wind speed profile retrieved from meteorological forecasts. To illustrate our advance we show the values of these parameters recorded during a 36-hour, continuous demonstration of the instrument. Due to its portability and ability to work in stronger turbulence, the 24hSHIMM can also operate in urban locations, providing the field with a truly continuous, versatile turbulence monitor for all but the most demanding of applications.