Paper
19 July 2016 Detector modules and spectrometers for the TIME-Pilot [CII] intensity mapping experiment
Jonathon Hunacek, James Bock, C. Matt Bradford, Bruce Bumble, Tzu-Ching Chang, Yun-Ting Cheng, Asantha Cooray, Abigail Crites, Steven Hailey-Dunsheath, Yan Gong, Chao-Te Li, Roger O’Brient, Erik Shirokoff, Corwin Shiu, Jason Sun, Zachary Staniszewski, Bade Uzgil, Michael Zemcov
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Abstract
This proceeding presents the current TIME-Pilot instrument design and status with a focus on the close-packed modular detector arrays and spectrometers. Results of laboratory tests with prototype detectors and spectrometers are discussed. TIME-Pilot is a new mm-wavelength grating spectrometer array under development that will study the Epoch of Reionization (the period of time when the first stars and galaxies ionized the intergalactic medium) by mapping the fluctuations of the redshifted 157:7 μm emission line of singly ionized carbon ([CII]) from redshift z ~ 5:2 to 8:5. As a tracer of star formation, the [CII] power spectrum can provide information on the sources driving reionization and complements 21 cm data (which traces neutral hydrogen in the intergalactic medium). Intensity mapping provides a measure of the mean [CII] intensity without the need to resolve and detect faint sources individually. We plan to target a 1 degree by 0.35 arcminute field on the sky and a spectral range of 199-305 GHz, producing a spatial-spectral slab which is 140 Mpc by 0.9 Mpc on-end and 1230 Mpc in the redshift direction. With careful removal of intermediate-redshift CO sources, we anticipate a detection of the halo-halo clustering term in the [CII] power spectrum consistent with current models for star formation history in 240 hours on the JCMT. TIME-Pilot will use two stacks of 16 parallel-plate waveguide spectrometers (one stack per polarization) with a resolving power R ~ 100 and a spectral range of 183 to 326 GHz. The range is divided into 60 spectral channels, of which 16 at the band edges on each spectrometer serve as atmospheric monitors. The diffraction gratings are curved to produce a compact instrument, each focusing the diffracted light onto an output arc sampled by the 60 bolometers. The bolometers are built in buttable dies of 8 (low freqeuency) or 12 (high frequency) spectral channels by 8 spatial channels and are mated to the spectrometer stacks. Each detector consists of a gold micro-mesh absorber and a titanium transition edge sensor (TES). The detectors (1920 total) are designed to operate from a 250 mK base temperature in an existing cryostat with a photon-noise-dominated NEP of ~2 * 10-17 WHz-1-2. A set of flexible superconducting cables connect the detectors to a time-domain multiplexing SQUID readout system.
© (2016) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Jonathon Hunacek, James Bock, C. Matt Bradford, Bruce Bumble, Tzu-Ching Chang, Yun-Ting Cheng, Asantha Cooray, Abigail Crites, Steven Hailey-Dunsheath, Yan Gong, Chao-Te Li, Roger O’Brient, Erik Shirokoff, Corwin Shiu, Jason Sun, Zachary Staniszewski, Bade Uzgil, and Michael Zemcov "Detector modules and spectrometers for the TIME-Pilot [CII] intensity mapping experiment", Proc. SPIE 9914, Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy VIII, 99140L (19 July 2016); https://doi.org/10.1117/12.2233762
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Cited by 3 scholarly publications.
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KEYWORDS
Spectrometers

Sensors

Prototyping

Silicon

Galactic astronomy

Stars

Diffraction gratings

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