Precision of the Chinese Space Station Telescope (CSST) stellar radial velocities

Abstract The Chinese Space Station Telescope (CSST) spectroscopic survey plans to deliver high-quality low-resolution ( R > 200) slitless spectra for hundreds of millions of targets down to a limiting magnitude of about 21 mag, covering a large survey area (17 500 deg 2 ) and a wide wavelength ra...

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Bibliographic Details
Published inResearch in astronomy and astrophysics Vol. 21; no. 4; pp. 92 - 137
Main Authors Sun, Yang, Deng, Ding-Shan, Yuan, Hai-Bo
Format Journal Article
LanguageEnglish
Published Beijing National Astronomical Observatories, CAS and IOP Publishing Ltd 01.05.2021
IOP Publishing
Department of Astronomy,Beijing Normal University,Beijing 100875,China
Subjects
Calibration
Massive stars
Metallicity
methods: data analysis
methods: statistical
Polls & surveys
Signal to noise ratio
Space stations
Spectroscopy
stars: fundamental parameters
stars: kinematics and dynamics
Stellar spectra
Uncertainty
Velocity
stars:kinematics and dynamics
methods:statistical
stars:fundamental parameters
methods:data analysis
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Summary:Abstract The Chinese Space Station Telescope (CSST) spectroscopic survey plans to deliver high-quality low-resolution ( R > 200) slitless spectra for hundreds of millions of targets down to a limiting magnitude of about 21 mag, covering a large survey area (17 500 deg 2 ) and a wide wavelength range (255–1000 nm by three bands GU, GV, and GI). In this work, we use empirical spectra of the Next Generation Spectral Library to simulate the CSST stellar spectra at R = 250, and investigate their capabilities in measuring radial velocities. We find that velocity uncertainties depend strongly on effective temperature, weakly on metallicity for only FGK stars, and hardly on surface gravity. It is possible to deliver stellar radial velocities to a precision of about 3 km s −1 for AFGKM stars, and about 10 km s −1 for OB stars, at signal-to-noise ratio (SNR) of 100. Velocity uncertainties using single GU/GV/GI band spectra are also explored. Given the same SNR, the GU band performs best, the GV band the second best, and then the GI band. The effects of spectral normalization and the imperfect template on velocity measurements are investigated and found to be very weak. The uncertainties caused by wavelength calibration are considered and found to be moderate. Given the possible precision of radial velocities, the CSST spectroscopic survey can enable interesting science such as searching for hyper-velocity stars. Limitations of our results are also discussed.
ISSN:1674-4527
2397-6209
DOI:10.1088/1674-4527/21/4/92