The Mini-Calorimeter detector for the AGILE mission

The Mini-Calorimeter detector for the AGILE mission C. Labanti a, A. Argan b, A. Bulgarelli a, G. di Cocco a, M. Galli c, F. Gianotti a, M. Marisaldi a, A. Mauri a, E. Rossi a, M. Tavani d, A. Traci a, M. Trifoglio a a IASF/CNR Sezione di Bologna, Italy b IASF/CNR Sezione di Milano, Italy c ENEA Bologna, Italy d IASF/CNR Sezione di Roma, Italy

AGILE Astrorivelatore Gamma ad Immagini LEggero (Light Gamma-ray Imager for Astrophysics) The AGILE Mission combines, for the first time in high-energy astrophysics a wide field-of-view instrument sensitive in the 30 MeV - 50 GeV band, with a 10-40 kev X-ray monitor. It will explore a wide variety of celestial phenomena including active galactic nuclei (AGNs), gamma-ray bursts (GRBs), diffuse emission, pulsars, and other Galactic sources. Mass: Power 190 kg (120 kg payload) 135 W (46 W payload) Launch: Autumn 2005 Orbit: Mission lifetime: Equatorial at ~ 560 km 3 years minimun AGILE is a small mission of the Italian Space Agency (ASI), the involved institute are: IASF-CNR INAF, Milano Univ. di Trieste and INFN CIFS IASF-CNR INAF, Roma IASF-CNR INAF, Bologna Univ. Roma 2 and INFN Univ. Roma 1 and INFN ENEA Roma ENEA Bologna Homepage: http://agile.mi.iasf.cnr.it/

AGILE Integrated Payload Anticoincidence P/L Detector Super Agile (10 40 kev) System Harness & Heaters Silicon Tracker Minicalorimeter (.3 200 MeV) GRID (30 MeV 50 GeV) P/L Shell P/L Data Handling Unit P/L Power Supply Unit Star Sensors Units Courtesy of AST GPS Units

Instrument Performance AGILE-GRID En. range ~ 30 MeV- 50 GeV Aeff (400 MeV, 0º) ~570 cm2 FOV ~ 3 sr PSF (400 MeV, 0º) ~1.22º Source Loc. Acc. ~ 5' - 20' DE/E ~ 1 Deadtime < 200 msec Super--AGILE En. range ~ 10-40 kev Aeff (13.1 kev, 0º) ~ 80 cm2 FOV ~ 0.8 sr PSF (pixel size) ~ 6' Source Loc. Acc. ~ 1' - 3' DE < 4 kev Deadtime ~ 5 msec Minicalorimeter En. range ~ 0.3-200 MeV DE ~ 1 MeV Aeff (1-10 MeV, 0º) ~500 cm2 Deadtime ~ 5 msec

MCAL on AGILE TASK In the GRID operation mode, supply energy and position informations on the particles detected by the Tracker. In the BURST operation mode supply time and energy informations of impulsive gamma events. Continuolsly supply the background behaviour via ratemeters in variuos energy ranges ARCHITECTURE MCAL is made of 30 CsI(Tl) scintillator bars. The bars are arranged in two layer of 15 elements orthogonal to each other Each bar is optically coupled to 2 Photodiodes (PD). The signals of each bar are feed to the GRID and BURST chain where they are analysed at the same time

MCAL assembly

MCAL Bar detectors CsI(Tl) scintillator 375 23 15 mm 2 custom PIN PD for each bar (Si active area 256 mm 2, 130 pf, I l 1.5 na @ 20 C) The scintillation light collected by one PD depends from the interaction position x and the energy deposited E I E*exp(- x) in the range 0.002 0.045 cm -1 depending from surface treatment and wrapping Weighting the signals A end B from the two PD of one bar the energy and position can be evaluated x ln (A/B) E sqrt(a*b)

Bar surface treatment Light output (e-/kev) 26 22 18 14 Wide side: grinded, Narrow side: polished, Att. coeff. = 0.025 cm-1 Wide side: grinded, Narrow side: grinded, Att. coeff = 0.039 cm-1. Wide side: polished, Narrow side: grinded, Att. coeff. = 0,0107 cm-1. 10 0 4 8 12 16 20 Distance from PDs (cm) Wide side: polished, Narrow side: polished, Att. coeff. = 0.002 cm-1.

Flight bar design The bars with PD glued, wrapping etc. are hoisted in a carbon fibre structure to give modularity and strenght. Two prototype bars have been tested in the MCAL temperature ranges (operative, non-operative etc).

Plane of the signals from PDs Test with a collimated 22 Na source (511 and 1275 kev) 1 cm from PD A 18.75 cm from PD A 36.5 cm from PD A

Energy and position evaluation 1500 Energy reconstruction 1000 counts 500 1500 1 counts 1000 0 0 100 ch (A.U.) 200 300 30.5 14 dist. from PD 500 0 0 100 200 ch 300 400 500 36.5 Collimated 22 Na spectra collected by one PD for different source positions. 1 18.7 dist. from PD 12000 Position reconstruction 8000 counts 4000 0 0 32 64 96 ch. U. A. 1 14 dist. from PD 30.5

Light output vs Temp. 25.0 PD A 40 25.0 PD B 20.0 30 20.0 e-/kev 15.0 20 10 e-/kev 15.0 10.0 0 10.0 5.0 0 10 20 30 40 dist from PD [cm] -10-20 5.0 0.0 10.0 20.0 30.0 40.0 dist from PD [cm] 24.0 Light output near the PD vs T e-/kev 22.0 PD A PD B 20.0-20 -10 0 10 20 30 40 Temp C

Energy and position resolution 280.0 1275 kev peak channel 40 128.0 Position reconstruction @ 1275 kev E in ch 260.0 240.0 30 20 10 0 pos in ch 96.0 64.0 32.0 220.0 0 10 20 30 40 dist from PD A [cm] -10-20 0.0 0 10 20 30 40 dist from PD A [cm] 15.0 1275 kev peak % resolution FWHM @ 4 Error (1 ) in position reconstruction with Na-22, all Energies 3 % 10.0 cm 2 5.0 0 10 20 30 40 dist from PD A [cm] 1 0 5 10 15 20 25 30 35 40 dist from PD A [cm] All parameters evaluated with pre-amps shoving ~ 850 e - rm noise at room Temp.

MCAL operative modes 1) GRID: MCAL is slave of the Tracker. On command all the PD signals are stretched, AD converted and sent to the Data Handling. Operative range for each bar is 1 500 MeV. MCAL can start a GRID event if it detects more than 50 MeV on the whole system. The FEE can handle an event rate up to 1300 Hz. 2) BURST: MCAL indipendently detects events in the range 250 kev e 250 MeV. The AD converted data are processed in the Data Handling for transient event search. The FEE can handle an event rate up to 500 khz. MCAL FEE deals, at the same time, the processing of the two modes as well as the generation of House_Keeping data, Telecommands implementation etc. Energy resolution FWHM Position resolution (1 ) Time resolution (Burst) Energy Range Event time of analysis ~ 10 % @ 1 MeV ~0.7% @ 100 MeV ~20 mm @ 1 MeV ~2 mm @ 100 MeV ~2 ms GRID: 1 500 MeV BURST: 0.25 250 MeV GRID: ~60 ms BURST: ~10 ms/bar

MCAL FEE Overall power consumption: 5 W PD s charge preamplifiers: ~ 850 e- rms GRID, BURST, HK & TC functions contained in two boards with the same footprint of the bar assembly Simplified Engeneering Model of MCAL DFEE Each board includes the analogue chains for 15 bars. The circuits for GRID operations up to A/D conversion are contained in one board, the BURST operations are all developed in the other board.

MCAL Test Equipment A dedicated Test Equipment has been realized for SEM MCAL test The system is based on a VME bus with a board for each MCAL I/F (GRID, BURST, HK-TC) Optical cable VME Crate Science Console Host Computer Br i d g e B U r s t G RI D H K T C MCAL SEM 8 bars DFEE SEM

Lato A Lato B Test with particles MCAL SEM (with early prototype bar detectors) has been tested both in laboratory and, togheter with a prototype Tracker and AC, with particle beam (CERN T-9 and T-11) Set-up misure CERN Lato B Tracker P4 P3 P2 P1 MCAL Beam 5 6 7 Strip 1 8 4 1 2 3 Lato A Strip 384 variable 18 mm

Test with particles 160 Bar 2 Counts 140 120 100 80 60 90 60 45 40 20 0 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 Energy (MeV) Energy lost by m of 2 GeV/c impinging on MCAL with various angle Difference between the position of interaction of m impinging on one MCAL bar evaluated with the PD data and with the projection of the position evaluated in the Tracker.

Conclusions AGILE will be launched at the end of 2005 The prototype studies on MCAL detector and electronics have demonstated the validity of the choosen design