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FAST Project and its Science Goals. Five hundred meter Aperture Spherical radio Telescope. Zhu, Ming (on behalf of the FAST team) National Astronomical Observatories Chinese Academy of Sciences. 2012 April 2. content Introduction to the FAST project General technical specifications
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FAST Project and its Science Goals Five hundred meter Aperture Spherical radio Telescope Zhu, Ming (on behalf of the FAST team) National Astronomical Observatories Chinese Academy of Sciences 2012 April 2
content • Introduction to the FAST project • General technical specifications • Last Status • FAST Science
Five hundred meter Aperture Spherical Telescope Unique Karst depression as the site Active main reflector Cable - parallel robot feed support
Guiyang Site Surveying in Guizhou Location: N25.647222º E106.85583° Site: the Karst region in south Guizhou Province
FAST model construction process 1. tower 2. girder ring 4. cable & node 3. cement depression 5. actuator
Sky coverage ZA 30 deg ZA 40 deg ZA 60 deg FAST Zenith Opening angle - sky coverage ZA 56 deg Sky coverage FAST vs. Arecibo
Frequency range 0.13 0.327 1.42 3 4 5 (GHz) 8 In layout 2000 First phase Second phase HI surveying 70MHz EoR z~20 Pulsar 300MHz 5.2GHz VLBI HCOOH 17 Lines HC5N(4) CH(4) CH4 H2CO(6) CH3OH OH(4) SETI Water hole Space science S Band C Band X Band
Observatory Receivers Measurements Observatory building Receivers Mark stone Backend Computing center Laser total station Disaster prevention Optical fiber Photogrammetry Field bus Tension monitoring Cables AB-rotator & Stewart Earth work Winches Drainage Capstan Elements Exploration Tower Main cable net Active Reflector Feed support Site 3.Technical plan – critical technology Site Active Reflector Feed support Measurements Receivers Observatory
下拉索 索节点 主索网 周边支承结构 地锚 背架结构 主索网 面板 下拉索 促动器 防躁墙 挡风墙 节点 健康监测系统 Structure of active reflector • 500m girder built around hills supported by • 50 pillars • Backup consists of ~7000 steel strands • actuated by ~2300 down tied cables driven by • winches anchored into ground • Errors 5.0 mm r.m.s in total
Feed support • Three main parts of cabin suspension • Cable network - adjustable system • Stewart Platform - secondary adjustable system • Close loop control F=0.4665R Focus surface
Measurement –precise, quick and in long distance • Task 1: 3-D spatial positions of focus cabin • Large working range up to 300 m • Errors ~1 mm • Sampling rate > 10 Hz Task 2: profiles of main reflector • Number of targets ~2400 • ~1000 in illuminated area • Accuracy 1~2mm • Sampling interval 10 sec ~ few min
DGPS:10Hz;1cm CCD:20Hz;0.5cm Laser Tracker:1KHz;0.05mm IMU:0.1 Measuring Total station
Photogrammetry Surveying reflector profile 1000 nodes within illuminated area to be scanned in real-time period ~ 1 min
Main Control Computer Power Monitoring Feed Control Computer Reflector Control Computer Location Reference Time Reference Laser Measurement Cable Tension Measurement Inertial Measurement Reflector Measurement Cable Tension Measurement Main Control Diagram
Feed + polarizer E/O O/E Mixer LNA Pulsar HI line VLBI SETI Receiver Diagnostics Receiver -- Schematic Diagram multi
x y z L-band Multi-beamreceivers and its prototyping
接收机与终端- 2 密云模型观测情况 密云模型低频馈源 EMI测试
FAST sciences • Neutral Hydrogen line (HI) survey • Pulsar research • VLBI network • Molecular line study (including recombination lines, masers) • Search for Extraterrestrial Intelligence (SETI)
FAST all-sky HI survey • Using a 19 beam L-band receiver to map 2.3π sterradians FAST sky at 40 sec per beam, doable in 1-2 yrs. • Expect about 1 million detections (Duffy et al. 2008) with MHI< 1011 Mout to z ~ 0.15 in a range of environments including Coma, Hydra, Ursa Major, Persues-Pisces supercluster plus neighboring voids. • Large HI database for T-F relation, peculiar velocity study of the local universe with a larger volume. • Extend ALFALFA Sky coverage
Duffy et al (2008) Number of galaxies to be detected per day (18h) using FAST 19 beams with different integration time ---- 6 sec ---- 60 sec ---- 600 sec ---- 6000 sec ---- 60000 sec
Xuelei Chen Veff vs scale ¼ sky coverage survey by FAST ---- 6 s 44 days ---- 12 s 88 days ----1 min 440 days Duffy et al Spectra errors
Deep mapping of Nearby Galaxies • To map a 4 square degree area, with an integration time of 10 minute per beam, in 10 hours we can reach a 3σ sensitivity of 1.5 x1017 cm-2 per 2.1 km/s channel. • Select regions of different environments, • void, big galaxies, clusters …
Kacprzak et al. 2010 ΛCDM COSMOLOGICAL GALAXY SIMULATIONS
How is gas accreted from the IGM onto galaxies? • low NHI gas seen around M 31 and M 33 Braun &Thilker 2004
FAST WALLABY: NHI~2x10^19 cm-2 DINGO deep: NHI~2.6x 10^18 cm-2 DINGO u-deep: NHI~1.2x10^18 cm-2 Prochaska et al. 2010
HI map of M31 Braun & Thilker 2003
Xuelei Chen – Estimated FAST detection sensitivity of 1 min & 1 h Line width 30km/s,S/N -10 Kravtsov - Simulation on dark matter distribution in a normal galaxy
Searching for High Z HI and OH Megamaser Arecibo 0.1 < z < 0.45 0◦ < < 37◦ Smin ~0.6 mJy 53 OHM FAST 0.1 < z < 5 0◦ < < 70◦ Smin ~0.1 mJy ~3000 OHM
The simulated uv-coverage of EVN+FAST for sources of Declination 10 and 60 degree
Search for binary SMBH • Galaxy mergers yield inspiraling, binary, and recoiling black holes that may be detectable with high resolution VLBI search for off-nuclear and binary SMBHs • FAST+VLBI
Summary FAST has very high sensitivity and large coverage of the northern sky Good for searching for weak signals, low surface brightness structures FAST has the potential to make great contributions to HI and pulsar studies and VLBI observations First light expected in 2016 Website: fast.bao.ac.cn