Development of a prototype for Fluorescence detector Array of Single-pixel Telescopes (FAST) T. Fujii 1,2, P. Privitera 1, J. Jiang 1 construction is still, A. Matalon 1 in development, P. Motloch 1, M. Casolino 3, Y. Takizawa 3, M. Bertaina 4, J. N. Matthews 5, K. Yamazaki 6, B. Dawson 7, M. Malacari 7 1 KICP University of Chicago, 2 ICRR University of Tokyo, 3 RIKEN, 4 University of Torino, 5 University of Utah, 6 Osaka City University, 7 University of Adelaide 2014/Oct/15, UHECR 2014 fujii@kicp.uchicago.edu
Physics Goal and Future Prospects Origin and Nature of UHECRs Particle Interaction at the Highest Energies 5 - years Exposure and full sky coverage TA 4 + Auger JEM-EUSO: Pioneer detection from space and sizable increase of exposure Detector R&D Radio, SiPM detector, FD or SD Precision measurement Auger Muon Upgrade Low energy enhancement (TALE+TA-muon+NICHE, Auger infill+heat+amiga) - 20 years P. Privitera et al., KICP workshop, September, 2013 Next Generation Observatories In space (0 exposure) Ground ( exposure with high quality events) 2
Fluorescence detector Array of Target : > 19.5 ev, UHE nuclei and neutral particles Huge target volume Fluorescence detector array Fine pixelated camera (Auger, TA) Single-Pixel Telescopes (FAST) Too expensive to cover a large area Low cost single pixel telescope (FAST) Shower profile reconstruction by given geometry
Fluorescence detector Array of Single-Pixel Telescopes (FAST) 20 km Reference design: 1 m 2 aperture, 15 15 FoV per single PMT 12 Telescope, 48 PMTs, 30 360 FoV in each station. 3 2 1 Photons at diaphragm 1 If 127 stations are installed with 20 km spacing, a ground coverage is ~ 40,000 km 2 Photons at diaphragm 56 EeV zenith 50 0 Photons at diaphragm 3 2 4 16 Geometry: Radio, SD or three coincidence of FAST.
Window of Opportunity at EUSO-TA Telescope Array, Utah, USA Black Rock Mesa site EUSO-TA optics EUSO prototype Temporally borrow the EUSO-TA optics at the TA site. M. Casolino (RIKEN), M. Bertaina, M. Marengo, F. Borotto, B. Giraudo (INFN-Torino) Two Fresnel lenses (+ 1 UV acrylic plate in front for protection) 1 m2 aperture, 14 14 FoV FAST reference design. Installation in February 2014, test measurements in April and June 2014. Collaboration between Pierre Auger, Telescope Array and JEM-EUSO. 5
Camera of FAST PMT 8 inch R5912-03 E7694-01(AC coupling) MUG6 UV band pass filter YAP (YAIO3: Ce) scintillator with 241 Am (50 Hz) to monitor gain stability. Np.e. / 0 ns YAP Signal 6
DAQ System TAFD external trigger, 3~5 Hz Anode & dynode Signal Camera of FAST 15 MHz low pass filter High Voltage power supply, N1419 CAEN Portable VME Electronics - Struck FADC 50 MHz sampling, SIS3350 - GPS board, HytecGPS2092 Amplifiers R979 CAEN Signal 7 All modules are remotely controlled through wireless network. 777,Phillips scientific Signal 50
Installation in February 2014 1 2 3 4 5 6 7 8 9 Start observation!! 8
Operation in Clear Night Night sky background Become quieter background Close Electronic noise level Open 12.7 C 4.6 C Variance is proportional to PMT current. Electronic noise is negligible with regard to night sky background. +8% YAP signal 7 hours data taking Good gain stability during data taking, consistent with PMT gain temperature dependence of -1%/
GPS Timing and CLF Signal Central Laser Facility Vertical UV laser shooting every 30 minutes, 21 km from FAST, Hz, 2.2 mj, 300 shots Entries 3000 2500 2000 1500 00 Histogram Entries 28592 Mean 20.86 RMS 0.09781 500 Np.e. / (0 ns) 0 19.5 20 20.5 21 21.5 22 22.5 Average of 223 shots FAST-TAFD timing resolution, 0 ns. (20.9 µs is the TAFD trigger processing time.) GPS timing difference (FAST - TAFD) [µs] laser signal ~ 19.5 ev at 21 km peak signal ~ 7 p.e. / 0 ns (σp.e. = 12 p.e.) at the limit of detectability
Preliminary CLF Simulation Np.e. / (0 ns) Data Y. Takizawa (RIKEN) Directional sensitivity N p.e. Np.e. / (0 ns) 7 6 5 4 3 Simulation Efficiency 2 1 0 0 500 00 1500 2000 2500 3000 3500 4000 Time (20 ns / bin) 11
Portable Laser Signal Np.e. / (0 ns) FAST / (0 ns) N p.e. 450 400 350 Single laser shot Simulation 300 250 200 150 0 50 0 0 500 00 1500 2000 2500 3000 3500 4000 Time (20 ns / bin) Vertical UV laser with same energy of CLF (~ 19.5 ev) at 6 km from FAST. Operated by K. Yamazaki (OCU) Peak signal ~ 300 p.e. / 0 ns. All shots are detected. Np.e. / (0 ns) TAFD FAST FOV Hit Cloud Expected signal TAFD/FAST: (7 m 2 aperture 0.7 shadow 0.9 mirror) / (1 m 2 aperture 0.43 optics efficiency) ~ 12
Shower Signal Search TAFD log(e/ev)=18.0 FAST FoV We searched for FAST signals in coincidence with TAFD showers in the FAST FoV. Np.e. / (0 ns) FAST Data set: April and June observation, 19 days, 83 hours. 16 candidates found. Low energy showers as expected. 13
Example of Signal Candidates FAST TAFD log(e/ev)=17.2 log(e/ev)=18.3 log(e/ev)=17.9 14
Comparison with simulated signal using result reconstructed by TAFD / (0 ns) N p.e. 60 50 40 30 log(e/ev)=17.2 Simulation / (0 ns) N p.e. 50 40 30 log(e/ev)=18.0 Simulation 20 20 0 0 500 00 1500 2000 2500 3000 3500 4000 Time (20 ns / bin) 0 0 500 00 1500 2000 2500 3000 3500 4000 Time (20 ns / bin) Data Data A signal location is fluctuated within the TAFD trigger frame of 12.8 µs. 15
Distance vs Energy (from TAFD) for Candidates Impact parameter [km] 2 April+June RUN Preliminary Detectable Np.e. / (0 ns) 1 17 17.5 18 18.5 19 19.5 20 log (E (ev)) Figure 14: Distribution of the impact parameter as a function of the primary energy reconstructed by TA for shower candidates detected by the FAST prototype. The line indicates the maximum detectable distance by the FAST prototype (not fitted). Almost! log(e/ev)=19.1 FAST FoV log(e/ev)=18.1 16
Simulation Study 4 PMTs Telescope Reconstruction efficiency loge Proton Iron 18.5 0.65 0.56 19.0 0.88 0.89 19.5 0.99 1.00 FAST with 20 km spacing With smearing SD accuracy of geometry, Xmax resolution of FAST is 30 g/cm 2 at 19.5 ev. 0% efficiency at 19.5 ev Under implementing a reconstruction by only FAST. 17 Entries 600 500 400 300 200 0 Iron Proton 19.5 0 400 500 600 700 800 900 00 10 1200 1300 1400 2 Reconstructed X max [g/cm ] Proton EPOS Iron EPOS ev f Including = 1.17 Xmax resolution
Summary and Future Plans Promising results from the first field test of FAST concept: very stable and simple operation robust behavior under night sky background (gain stability, a single bright star does not matter when integrating over the large FAST FOV) laser shots and shower candidates detected sensitivity is consistent with simulated expectation Very successful example of Auger, TA, JEM-EUSO collaboration. Several improvements possible, e.g. high Q.E. PMT, narrow UV pass filter, mirror design, reconstruction method, etc. Next step: full 30 30 prototype. 18 Impact parameter [km] 2 Preliminary Detectable 1 17 17.5 18 18.5 19 19.5 20 log (E (ev))
Backup 19
Coverage and the number of FAST stations 20 km 173 km 2 L = 4 Nst=61 S = 16,608 km 2 20 L N_st S'[km^2] Cost'M$USD c 0 1 0 0.1 1 7 38 0.7 2 19 4152 1.9 3 37 9342 3.7 4 61 16608 6.1 5 91 25950 9.1 6 127 37368 12.7 7 169 50862 16.9 8 217 66432 21.7 9 271 84078 27.1 331 3800 33.1 11 397 125598 39.7 12 469 149472 46.9 13 547 175422 54.7 14 631 203448 63.1 15 721 233550 72.1 16 817 265728 81.7 17 919 299982 91.9 18 27 336312 2.7 19 1141 374718 114.1 20 1261 415200 126.1
Gain Calibration by LED in Laboratory 1 p.e. LED pulse with 2500 V Gain 7 6 5 Gain 4 908 V -> 5 4 Integrated counts 21 600 800 0012001400160018002000220024002600 High Voltage [V]