Astronomical instrumentation

VIRUS: status and performance of the massively-replicated fiber integral field spectrograph for the upgraded Hobby-Eberly Telescope

Ground-based and Airborne Instrumentation for Astronomy VII Society of Photo-optical Instrumentation Engineers (2018)

Authors:

G Hill, A Kelz, H Lee, P MacQueen, TW Peterson, J Ramsey, BL Vattiat, DL DePoy, N Drory, K Gebhardt, JM Good, T Jahn, H Kriel, JL Marshall, Tuttle, G Zeimann, E Balderrama, R Bryant, B Buetow, T Chonis, G Damm, MH Fabricius, D Farrow, J Fowler, C Froning, DM Haynes, BL Indahl, J Martin, F Montesano, E Mrozinski, H Nicklas, E Noyola, S Odewahn, A Peterson, T Prochaska, S Rostopchin, M Shetrone, G Smith, JM Snigula, R Spencer, A Westfall, T Armandroff, R Bender, Gavin Dalton, M Steinmetz

Abstract:

The Visible Integral-field Replicable Unit Spectrograph (VIRUS) consists of 156 identical spectrographs (arrayed as 78 pairs, each with a pair of spectrographs) fed by 35,000 fibers, each 1.5 arcsec diameter, at the focus of the upgraded 10 m Hobby-Eberly Telescope (HET). VIRUS has a fixed bandpass of 350-550 nm and resolving power R~750. The fibers are grouped into 78 integral field units, each with 448 fibers and 20 m average length. VIRUS is the first example of large-scale replication applied to optical astronomy and is capable of surveying large areas of sky, spectrally. The VIRUS concept offers significant savings of engineering effort and cost when compared to traditional instruments.

The main motivator for VIRUS is to map the evolution of dark energy for the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX‡), using 0.8M Lyman-alpha emitting galaxies as tracers. The VIRUS array has been undergoing staged deployment starting in late 2015. Currently, more than half of the array has been populated and the HETDEX survey started in 2017 December. It will provide a powerful new facility instrument for the HET, well suited to the survey niche of the telescope, and will open up large spectroscopic surveys of the emission line universe for the first time. We will review the current state of production, lessons learned in sustaining volume production, characterization, deployment, and commissioning of this massive instrument.

Radial measurements of IMF-sensitive absorption features in two massive ETGs

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 475:1 (2018) 1073-1092

Authors:

SP Vaughan, RL Davies, S Zieleniewski, RCW Houghton

Exoplanet Atmospheres at High Spectral Resolution

ArXiv 1806.04617 (2018)

Abstract:

The spectrum of an exoplanet reveals the physical, chemical, and biological processes that have shaped its history and govern its future. However, observations of exoplanet spectra are complicated by the overwhelming glare of their host stars. This review chapter focuses on high resolution spectroscopy (HRS; R=25,000-100,000), which helps to disentangle and isolate the exoplanet's spectrum. At high spectral resolution, molecular features are resolved into a dense forest of individual lines in a pattern that is unique for a given molecule. For close-in planets, the spectral lines undergo large Doppler shifts during the planet's orbit, while the host star and Earth's spectral features remain essentially stationary, enabling a velocity separation of the planet. For slower-moving, wide-orbit planets, HRS aided by high contrast imaging instead isolates their spectra using their spatial separation. The lines in the exoplanet spectrum are detected by comparing them with high resolution spectra from atmospheric modelling codes; essentially a form of fingerprinting for exoplanet atmospheres. This measures the planet's orbital velocity, and helps define its true mass and orbital inclination. Consequently, HRS can detect both transiting and non-transiting planets. It also simultaneously characterizes the planet's atmosphere due to its sensitivity to the depth, shape, and position of the planet's spectral lines. These are altered by the planet's atmospheric composition, structure, clouds, and dynamics, including day-to-night winds and its rotation period. This chapter describes the HRS technique in detail, highlighting its successes in exoplanet detection and characterization, and concludes with the future prospects of using HRS to identify biomarkers on nearby rocky worlds, and map features in the atmospheres of giant exoplanets.

Simulating Surveys for ELT-MOSAIC: Status of the MOSAIC Science Case after Phase A

(2018)

Authors:

M Puech, CJ Evans, K Disseau, J Japelj, OH Ramírez-Agudelo, H Rahmani, M Trevisan, JL Wang, M Rodrigues, R Sánchez-Janssen, Y Yang, F Hammer, L Kaper, SL Morris, B Barbuy, J-G Cuby, G Dalton, E Fitzsimons, P Jagourel, the MOSAIC Science Team

A Framework for Prioritizing the TESS Planetary Candidates Most Amenable to Atmospheric Characterization

(2018)

Authors:

Eliza M-R Kempton, Jacob L Bean, Dana R Louie, Drake Deming, Daniel DB Koll, Megan Mansfield, Jessie L Christiansen, Mercedes Lopez-Morales, Mark R Swain, Robert T Zellem, Sarah Ballard, Thomas Barclay, Joanna K Barstow, Natasha E Batalha, Thomas G Beatty, Zach Berta-Thompson, Jayne Birkby, Lars A Buchhave, David Charbonneau, Nicolas B Cowan, Ian Crossfield, Miguel de Val-Borro, Rene Doyon, Diana Dragomir, Eric Gaidos, Kevin Heng, Renyu Hu, Stephen R Kane, Laura Kreidberg, Matthias Mallonn, Caroline V Morley, Norio Narita, Valerio Nascimbeni, Enric Palle, Elisa V Quintana, Emily Rauscher, Sara Seager, Evgenya L Shkolnik, David K Sing, Alessandro Sozzetti, Keivan G Stassun, Jeff A Valenti, Carolina von Essen