Post on 25-Feb-2016
description
Auger Fluorescence Detector
Center for Cosmological Physics Enrico Fermi Institute
Mini-Symposium on the Auger Observatory
October 4, 2002
Giorgio Matthiae University of Roma II and INFN
The Auger Observatory 4 peripheral stations (eyes) 6 fluorescence telescopes / station Azimuthal angle of view 1800
Los Leones, Coihueco, Los Morados, Norte
Los Leones building
Coihueco FD building
Installation of the mirror supports
The FD telescope
Spherical mirror
PMT camera
Diaphragm
UV Filter, corrector ring Shutter
The Schmidt optics
C
Spherical aberration Coma aberration
Diaphragm Coma
suppressed
C
C
C
spot
F
Spherical focal surface
Design of the telescopesBasic parameters defined from the requirement of accurate measurement of the shower profileAperture: 1.5 m2 effective areaPixel size: 1.5 degrees
Schmidt optics:- coma aberration eliminated, circle of least confusion (spot) independent of the incident direction- aperture defined by the diaphragm- mirror size larger than for classical design
Spot size from spherical aberration: Δs ~ h (h/R)2 , Δθ = Δs/R ~ (h/R) 3
f/1 optics is a good compromise: R = 3.4 mDiaphragm diameter = 1.7 mSpot size : 0.5 degree (15 mm diameter)Pixel size: 1.5 degrees (45 mm )(the spot size is 1/3 of the pixel size)Field of view: 30 degrees azimuth 28.6 degrees elevation
The mirror systemShape nearly square due to square field of view.Size: 3.5 m x 3.5 m in order to avoid vignetting.Tesselation: 6 x 6 elements
• AluminumReflectivity: 88.0% (with Al2O3 coating)• Polished GlassReflectivity: 86.3% (with SiO2 coating)
The mirror elements are mounted on a rigid support structure. Each element can be accurately aligned independently.
Quality tests: - reflectivity at 370 nm- spot size obtained with point light source at the center of curvature
The FD telescope at Los Leones
PMT camera
mirror
Front end / read-outelectronics HV + LV
The corrector ring
factor 2 gain in light collection
The ring lenses (aspherical profile) correct the additional spherical aberration, keeping the spot size within the design value of 15 mm diameter
“Image” of a bright star
• The diameter of the spot is 15 mm as calculated.
• Good check of the alignment of the mirror elements
Fluorescence spectrum of nitrogen
The UV filter• The UV filter (M-UG6) matches the fluorescence spectrum of N2.
• Transmission: about 85 % at 350 nm, down to 20 % at 300 nm and 400 nm.
Reduction of “dark sky background” by nearly a factor of 8.
The camera• Array of 440 hexagonal pixels placed on the spherical focal surface. (22 rows x 20 columns)
• Pixel: PMT XP3062 with light collectors (45 mm wide)
The camera light collectors
• Light collectors to recuperate light incident between the PMTs or at the very edge of the photocathode.
• Plastic elements covered by aluminized mylar.
• Test with light source simulating the spot created by the mirror shows recuperation of light.
The FD camera
90 cm
440 PMTs
PMT active dividerBetter gain stability
passive
active
Dark sky background
FD electronics/triggerThe PMT signal is sampled at a rate of 10 MHz by FADC with 12 bits.
100 ns
First Level Trigger: Threshold regulated to keep single pixel rate at a given value, around 100 Hz.
Second Level Trigger: pattern recognition algorithm
5 adjacentpixels
Third Level Software Trigger: time – space correlation
FD data acquisition system
data
GPS time (hybrid operation)
Relative calibrationXe lamp + optical fibers
• Equalization of PMT gain• Stability of gain
Absolute calibrationDirect measurement of the response of each channel to a given flux of incident photons.
Wide light beam of uniform intensity provided by a UV LED (375 nm) and a flat cylinder (“drum”) with diffusing walls mounted outside the telescope aperture (ideally a “dome”).
The number of photons is obtained from Si photodetector calibrated at NIST
Absolute calibration
Preliminary result givesabout 5 photons / FADC count as average over all pixels of the camera
The drum mounted at Los Leones
Another method: remote laser of known intensity shot vertically in the atmosphere.Calculation of Rayleigh and aerosol scattering allows predicting flux of photons at the telescope.Similar result.
Surface Hybrid Surface Hybrid
Δθ 2.00 0.40 1.00 0.40
Δ core 80 m 30 m 40 m 30 m
ΔE/E 18 % 4.2 % 7.0% 2.5 %
ΔXmax 17 g/cm2
15 g/cm2
1019 eV 1020 eV
Hybrid vs. Surface Detector
43
2
2,3,4
Fraction of stereo FD
18 19 20
Log Energy (eV)
0
20
40
60
80
100
Shower geometry reconstruction
ψ
First step: reconstruct the Shower – Detector Plane (SDP)
χ0χi
RP
Shower
Telescope
ti (χi) = t0 + tg
χ0- χi
2
3 parameter fit : t0, RP and χ0
RP
c
First hybrid eventFD on line display
FD - SDmatching
FD shower candidate
100 ns time binTriggered
pixelsFADC traces
Background event Cosmic passing through PMTs
FD shower
crossing telescopes boundary
Laser shots reconstruction
degrees
Laser shot axis
ψ
Laser
Laser shots reconstruction
degrees
RP (Km)
Ψ (degrees)
Preliminary analysis
• Pixel calibration• Atmospheric corrections• Fluorescence yield• Estimate of Cherenkov light
• Reconstruction of the longitudinal profile
• Fit with Gaisser-Hillas form• Estimate of the energy and of the
depth of maximum Xmax
• Geometrical reconstruction from correlation of time vs. elevation angle χi
A “low-energy” shower fully contained in the atmosphere
Longitudinal profile and geometrical reconstruction
RP ~ 13 kmΘ ~ 570
χ0 ~ 820
Time vs. angle correlation for a laser shot at RP = 25 km
Very useful to understand the analysis of the real cosmic ray events !
Outlook
• All components of the 24 FD telescopes are financed. They are ready or ordered.
• Installation and commissioning of the telescopes in the two buildings (Leones and Coihueco) will be completed in 2003. This makes ½ of the overall FD.
• Some problem of funding for the construction of the remaining two buildings Morados and Norte but, good reasons for optimism !