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Scientific need, design and construction of a muon telescope for the Pierre Auger Observatory - PowerPoint PPT Presentation
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Scientific need, design and construction of a muon telescope for the Pierre Auger
Observatory
R. Alfaro Molina3, M. A. Diózcora Vargas Trevino5, J. C. D'Olivo1, H. Márquez-Falcón6, G. A. Medina-Tanco1, E. Nahmad-Achar1, G. Paic1 , M. E. Patino Salazar1, H. Salazar Ibarguen4, Federico Sanchez1, A. Sandoval3, J. F. Valdes Galicia2, S. Vergara Limon5, L. M. Villasenor6, A. Redondo Gonzalez7, N. Pacheco Gómez7, L. del Peral7, X. Bertou8, I. Allekotte8
(1) Instituto de Ciencias Nucleares , Universidad Nacional Autónoma de México, México, D.F., C.P. 04510.(2) Instituto de Geofísica, Universidad Nacional Autónoma de México, México, D.F., C.P. 04510.(3) Instituto de Física, Universidad Nacional Autónoma de México, México, D.F., C.P. 04510.(4) Instituto de Física, Universidad de Puebla, México, Puebla, C.P. 72570.(5) Facultad de Ciencias de la Electrónica, Grupo de Robótica, Benemérita Universidad Autónoma de Puebla, Av. San Claudio y 18 Sur C. U., Edif. 182, C.P. 72570, Puebla, México.(6) Universidad Michoacana de San Nicolás Hidalgo Morelia, Mich., C.P. 58040, México.(7) Universidad de Alcalá, España(8) Inst. Balseiro, Bariloche, Argentina
Scientific need, design and construction of a muon telescope for the Pierre Auger
Observatory
R. Alfaro Molina3, M. A. Diózcora Vargas Trevino5, J. C. D'Olivo1, H. Márquez-Falcón6, G. A. Medina-Tanco1, E. Nahmad-Achar1, G. Paic1 , M. E. Patino Salazar1, H. Salazar Ibarguen4, Federico Sanchez1, A. Sandoval3, J. F. Valdes Galicia2, S. Vergara Limon5, L. M. Villasenor6, A. Redondo Gonzalez7, N. Pacheco Gómez7, L. del Peral7, X. Bertou8, I. Allekotte8
(1) Instituto de Ciencias Nucleares , Universidad Nacional Autónoma de México, México, D.F., C.P. 04510.(2) Instituto de Geofísica, Universidad Nacional Autónoma de México, México, D.F., C.P. 04510.(3) Instituto de Física, Universidad Nacional Autónoma de México, México, D.F., C.P. 04510.(4) Instituto de Física, Universidad de Puebla, México, Puebla, C.P. 72570.(5) Facultad de Ciencias de la Electrónica, Grupo de Robótica, Benemérita Universidad Autónoma de Puebla, Av. San Claudio y 18 Sur C. U., Edif. 182, C.P. 72570, Puebla, México.(6) Universidad Michoacana de San Nicolás Hidalgo Morelia, Mich., C.P. 58040, México.(7) Universidad de Alcalá, España(8) Inst. Balseiro, Bariloche, Argentina
AMIGA & AMIGA & HEATHEAT
BASELINE BASELINE AugerAuger
Enhanced spectral region to be covered
G. Medina-Tanco
160000
Auger baseline design
Auger enhancements
AMIGA
2 SD graded infills
Buried muon counter scintillators
HEAT3 higher elevation FD telescopes
• Lower the full efficiency threshold of Auger down to 0.1 EeV
• Improve primary discrimination in the 2nd Knee & ankle region
G. Medina-Tanco
160000
HEAT + AMIGA layout & Auger
AMIGA layout
Graded infill SD arrayGraded infill SD array
1. Full efficient @ E > 1017 eV 5.9 km2 – 24 tanks – 433 m
2. Full efficient @ E > 3.5x1017 eV 23.5 km2 – 42 tanks – 750 m
+ buried muon scintillators:+ buried muon scintillators:
30m2 per tankdepth: ~ 2-3mMode: counters
G. Medina-Tanco
AMIGA SD-station [ (+e±) + ] & Scintillator [ ]
2-3m
Muon counter
Regular Auger water Cerenkov tank
EASEAS
groundground
G. Medina-Tanco
Scintillator strips are extruded polystyrene doped with fluors:
PPO (1%) and POPOP (0.03%)
Co-extruded TiO2 reflective coating
WLS fibers: Kuraray Y-11 175 ppm
1.2 mm diameter
Fiber is glued into groove and covered with reflective foil
AMIGA: muon counters – scintillator strips
Scintillator area at each station: 30 m2
Multianode PMTs64 pixels
M64 (Hamamatsu)
AMIGA: muon counters – scintillator strips
G. Medina-Tanco
Geant4 – Parent: muon - E = 5 GeV
~ 1.8 g/cm3
~ 3 m x
y
z
e-
e-
e-
e-
F. Sanchez & GMT
few mm
x
y
Geant4 – Parent: photon - E = 5 GeV
x
y
z
~ 2.5-3.0 m
~ 1.8 g/cm3
F. Sanchez & GMT
Geant4 – /e+/- Longitudinal profile
0.5 GeV 1.0 GeV
5.0 GeV 10.0 GeV
3 m F. Sanchez & GMT
3 m 3 m50 cm50 cm 50 cm50 cm
50 cm50 cm50 cm50 cm
1018 eV
Region of interest for the shielded muon counters
log E [GeV]
E d
N/d
E [
m-2]
EeV protons: distribution functions @ 200 m from core
This is where BATATABATATA enters into the picture
G. Medina-Tanco
Detector layoutDetector layout
BATATA: punch-through characterization system
y
x
e
2 m
~30 cm
~30 cm
~2.0 m
2 m
PMT + electronics
x
y
G. Medina-Tanco
t1=0 t2
t3
l
ll
|n3|=ct3
|n2|=ct2
n
Surface trigger array
G. Medina-Tanco
WHOLE BATATA ARRAY
l
ll
3
ls1
s3
s2
SDSD
G. Medina-Tanco
End-to-end simulationEnd-to-end simulation
End-to-end BATATA simulations
EAS
Core
Auger tank
200m
10m
10m
xy BATATA planes
AIRES
Geant4
10m
F. Sanchez & GMT (2007)
Trigger 3 tanks
End-to-end BATATA simulations:
Temporal & spatial unthinnings are applied
F. Sanchez & GMT (2007)
KurarayPreliminar simulation
KurarayPreliminar simulation
End-to-end simulationsEnd-to-end simulationsScint.Strip + optical fiber Scint.Strip + optical fiber
characterization & calibrationcharacterization & calibration
End-to-end simulationsEnd-to-end simulationsScint.Strip + optical fiber Scint.Strip + optical fiber
characterization & calibrationcharacterization & calibration
Actual measurementsActual measurements
180 cm180 cm100 cm100 cm
20 cm20 cm
In order to implement a realistic trigger threshold in the BATATA simulations, we are calibrating at present energy deposit vs signal (mV) via simulated optical photons at the PMT window.
In order to implement a realistic trigger threshold in the BATATA simulations, we are calibrating at present energy deposit vs signal (mV) via simulated optical photons at the PMT window.
End-to-end BATATA simulations
Trigger on energy deposit is applied
F. Sanchez & GMT (2007)
AMIGA application of BATATA simulation machine
Side viewSide view Top viewTop view
Tilted viewTilted view
Zoomed side viewZoomed side view
ee
ee
G. Medina-Tanco
Attenuation length
Muon surface efficiency & time of flight difference to PMT
Electromagnetic particles
Data analysis
Track discrimination:
End-to-end simulationsNN analysis
Multiparametric analysis
E. Nahmad & F. Sanchez & GMT (2007)
Front end electronics for one channel with a differential output LVDSFront end electronics for one channel with a differential output LVDS
1
2
3
64
AD8009
OUT OUT
MAX9201
C
O
N
E
C
T
O
R
DB0 DB7
WR
A0
A1
REF
PMT
H7564B
OUT A
DAC-TLC7226C
OUT B
OUT C
OUT D
IN 1A
G
G
VDD
C
O
N
E
C
T
O
R
D
I
F
SN55LVDS31
1Y
1ZG=10
Amplifier discriminator
Setup of the discriminator level
G. Medina-TancoS. Vergara, E. PatiS. Vergara, E. Patiño, M. A. D. Vargas Trevino & G. Paicño, M. A. D. Vargas Trevino & G. Paic
Electronics: front-end 64 channels board
S. Vergara, E. Patiño, M. A. D. Vargas Trevino & G. Paic
DAQ: Huberto Salazar (BUAP)
Luis Villaseñor (UMSNH)
Other applications
• Punch-through characterization • Measurement of the angular distribution functions at ground for , e±, • Check temporal (& spatial ?) un-thinning• Low energy directional background: sky maps
Astrophysics Space weather CR-climate connections
G. Medina-Tanco
Casing – another idea
y = 2 m
x = 2 m ~0.4 m ? ~0.15 m ?
inspection lids
Silicon filing ?
Simplest. But: Too large? Too heavy?
Casing requirements1. Buried life expectance: 5 yr2. Water-tight3. Corrosion free4. Salt resistant5. Maximum working temperature: 50 oC (at the electronic box)6. Can be opened and re-sealed in a non-destructive way (desirably) under field conditions.7. Sturdy enough as to survive shipping, handling and burying.8. Material: TBD9. Color: white or aluminum -- must be reflective10. Dimensions:
a. footprint 2m x 2.5 m ;b. Thickness:
1. scintillator section: ~1.2 cm (interior)2. Optical fiber bending section: 1.2 cm (interior)3. Electronic housing section: ~20 cm (internal)
1. Lid thickness: < 2 - 3 mm (?) -- x & y planes must be as much in physical contact as possible.2. Base thickness: TBD
11. Water-tight openings for circular and flat cables. Location must take into account optimal flat cable bending.
12. Support for cookie, PMT and (vertical) electronic board (must be rigid at T~50 oC)13. Optical fiber bending section must not collapse under a pressure of at least 600 g/cm2. A filling may be
used. Potting (rigid or fluid) may not be desirable). With fungicide.14. Longitudinal displacement of scintillator bars must be blocked. 15. Electronics / optical coupling inspection lid to be used under field conditions (w/o tightness compromise).16. Handles for crane17. Ensure the perpendicularity of x & y18. Ensure that different planes are aligned among themselves
Gustavo [email protected]
BATATA: current status
Design - General design: FROZEN (except exact depths of planes 1 & 2)
- Operating strategy: FROZENEnd-to-end simulations: 90% - Ongoing: calibration w/measurementsElectronics: 50% - Ongoing: frontend printing/assembling & FPGA Scintillator - 32m2 from Fermilab – built & delivered in TXoptical fiber - FROZEN – BicronPMT - FROZEN – 64 pix PMTCasing - started: CCADET - ICN - IG (UNAM)Solar power supply - Univ. de Alcalácontrol & processing software - Ongoing: ICN-UNAM / Univ. de AlcaláData analysis software: 70% - 2 startegies: multiparam. analysis & N-NetworksSD array: - Installation in Nov/2007: IB/BUAP/UMSNH/UNAM
Design - General design: FROZEN (except exact depths of planes 1 & 2)
- Operating strategy: FROZENEnd-to-end simulations: 90% - Ongoing: calibration w/measurementsElectronics: 50% - Ongoing: frontend printing/assembling & FPGA Scintillator - 32m2 from Fermilab – built & delivered in TXoptical fiber - FROZEN – BicronPMT - FROZEN – 64 pix PMTCasing - started: CCADET - ICN - IG (UNAM)Solar power supply - Univ. de Alcalácontrol & processing software - Ongoing: ICN-UNAM / Univ. de AlcaláData analysis software: 70% - 2 startegies: multiparam. analysis & N-NetworksSD array: - Installation in Nov/2007: IB/BUAP/UMSNH/UNAM
80%
G. Medina-Tanco
Tentative Chronogram
Assembly: November 2007Delivery: February 2007Installation: March 2008Operation starts: April 2008Stable operation: May 2008
Tentative Chronogram
Assembly: November 2007Delivery: February 2007Installation: March 2008Operation starts: April 2008Stable operation: May 2008
BATATA: (dynamical) cronogram
G. Medina-Tanco
