Sergio Ricciarini ~ INFN Firenze on behalf of PAMELA collaboration Vertex 2006 15 th International...

Sergio Ricciarini~

INFN Firenze

on behalf of PAMELA collaboration

Vertex 200615th International Workshop on Vertex Detectors

Perugia, 28 September 2006

PAMELA Silicon Trackerexperience and operation

Summary

Introduction.• The PAMELA experiment.

The magnetic spectrometer and silicon tracker.• Detectors and read-out electronics.

Tracker performances.• Preliminary analysis of a sample of data taken in flight.

Examples of events collected in flight by PAMELA.

S. Ricciarini – PAMELA Silicon Tracker – Vertex 2006, Perugia 28 September 2006

ITALY: • INFN Florence and Physics Department of Florence University • Istitute of Applied Physics “Nello Carrara”, Florence • INFN Bari and Physics Department of Bari University • INFN and Physics Department of Rome "Tor Vergata" • INFN Naples and Physics Department of Naples University • INFN Trieste and Physics Department of Trieste University • INFN National Laboratories, Frascati

GERMANY: Physics Department of Siegen University

SWEDEN: Royal Institute of Technology, Stockholm

RUSSIA: • Ioffe Physico-Technical Institute, St Petersburg • Cosmic Rays Laboratory, Moscow Engineering and Physics Institute, Moscow • Lab. of Solar and Cosmic Ray Physics, P.N. Lebedev Physical Institute, Moscow


PAMELA experiment Main scientific objectives:

• antiparticles in cosmic rays; • search for antimatter and dark matter;• cosmic-ray propagation; • solar modulation, solar physics.

Mission overview:• on-board Resurs-DK1 Russian satellite, launched from Bajkonur (Kazakhstan) 15 June 2006;• quasi-polar orbit 70° inclination, 350-600 km altitude; • long expected duration (> 3 years);

efficient rejection of atmospheric background (albedo); high statistics, also at lower energies (geomagnetic effect).

Design goals for PAMELA performance:

sensitivity in anti-He/He ratio ~ 10-7

particle kin. energy range

antiproton 80 MeV - 190 GeV(expected ~ 104/year)

positron 50 MeV - 270 GeV(expected ~ 105/year)

electron 50 MeV - 400 GeV

proton 80 MeV - 700 GeV

e- + e+ up to 2 TeV

nuclei Z ≤ 6 100 MeV/n - 200 GeV/n


operational

launch (rest)

Al containerfilled with N2 at 1 atm2 mm thick window

Primaryproduction annihilation m() = 964 GeV(Ullio 1999)

Main requirements: high-sensitivity antiparticle identification, precise momentum measure.

Time-Of-Flightplastic scintillator strips + PMT: trigger, albedo rejection; mass identification up to E ~ 1 GeV; charge identification from dE/dX.

Magnetic spectrometerwith microstrip Si tracker: charge sign and momentum from the curvature; charge identification from dE/dX.

Electromagnetic calorimeterW/Si sampling; 16.3 X0, 0.6 λI: discrimination e+ / p, e- / from shower topology; direct E measurement for e-.

PAMELA apparatus

max diameter: 102 cmheight: 130 cmweight: 470 kgpower: 355 W

p


Magnetic spectrometer Permanent magnet (5 modules): • Nd-Fe-B alloy elements, residual magnetization 1.3 T; • Al frames, tower height 44.5 cm; • geometric factor 21.5 cm2 · sr; • Bx ~ Bz < 0.1 By ;

• 3-axis map: 70000 points, 5 mm pitch.

Tracking system (6 planes, 8.9 cm apart): • 3 independent ladders per plane: • 2 Si microstrip sensors per ladder: • double sided, with double metallization on ohmic view; • integrated capacitive coupling;

• FE electronics (VA1 chips) integrated on hybrid boards. Si sensors hybrids

l a d d e r

VA1 chips

Bmean = 0.43 TBmax = 0.48 T

AD

C b

oard

s


Silicon detector ladder Sensor dimensions: 70.0 mm x 53.3 mm x 300 μm. Read-out:

• 1024 read-out channels per ladder view; • strip/electrode coupling ~ 20 pF/cm;• channel capacitance to ground: < 10 pF junction view, < 20 pF ohmic view.

Bias:• VY -VX = + 80 V fed through guard ring surrounding the strips.• Bias resistor: • junction: punch-through, > 50 MΩ; • ohmic: polysilicon, > 10 MΩ.

• Leakage current < 1 μA/sensor.


VA1 chip Main features:

• 1.2 µm CMOS ASIC (CERN - Ideas, Norway);• 6.2 mm · 4.5 mm chip area; 47 μm input pad pitch;• ± 2 V power rails;• 128 low-noise charge preamplifiers;• shaping time set to 1 μs;• ± 300 mV differential output range.

Operating point:• chosen for optimal compromise;• power consumption 1.0 mW/channel total dissipation 37 W for 288 VA1 (36864 channels);• voltage gain 7.0 mV/fC output saturation at ~ 10 MIP.


ADC stage:• 36 ADC sections, 1 ADC / ladder;• ADC are operated in parallel at 0.5 Msps;• event acquisition time 2.1 ms.

DSP stage:• 12 DSP on 2 boards, 1 DSP/view (ADSP2187L);• control logics on FPGA chips (A54SX);• typical data compression factor 15 ~ 4 kbyte/event;• typical compression time 1.1 ms.

Tracking system electronics General characteristics:

• segmentation/redundancy of power and functional sections;• devices qualified for radiation hardness (TID, SEE);• compact mechanical assembly;• limited total power consumption (63 W);• limited data bandwidth occupation (~ 10 Gbyte/day available).


flight data

calib

ratio

nphysics runphysics run

Tracker performances

Preliminary analysis of a sample of data taken in ~12 hours of flight.• Data show that the tracking system is working nominally as expected.

Thermal environment.

Noise performances.

Cluster multiplicity and total signal.

Signal correlation between X and Y views.

Signal/noise.

Charge discrimination capabilities.

Spatial resolution.

Momentum resolution.


Temperatures in flight After power-up temperature remains stable:

• < 1º C variations along orbit;• < 10º C difference between PAMELA off and on.

Heat from VA1 on hybrids radiated to the magnetic tower:• black IR absorbing painting on the walls;• heat released from magnetic tower to cooling loop (liquid iso-octane).


At power-up: 21º C(5000 s ~ 0.9 orbits)

8 days after power-up: 28º C(10000 s ~ 1.8 orbits)

Noise in flight


Noise

Pedestal

Y view (DSP 3)

Noise performance is nominal, as can be seen for a typical calibration taken in flight. Y (ohmic) view has worse performance because of double metallization.

X view (DSP 6)

Y view (DSP 3)X view (DSP 6)

N ~ 4 ADC counts N ~ 9 ADC counts

flight data flight data

flight data flight data

yellow line = ground data average

all planes

flight data - preliminary

all planes


one plane

flight data - preliminaryone plane

Cluster characteristics


Cluster inclusion cuts: S > 7 N (seed), S > 4 N (neighbours).

Signal/noise ratio, calculated as Σ(S/N) over the cluster channels.

This sample contains also non-MIP cosmic rays (He etc.). Typical average signal/noise measured at beam-test for orthogonally incident MIP:

56 (X view) 26 (Y view)

Signal/noise ratio



plane 1

Full charge discrimination capabilities studied with beam-test data (GSI Darmstadt, 2006).

• Fragmentation of 12C projectiles on different targets(Al, polyethylene).

Single-channel saturation at ~ 10 MIP affects B-C discrimination.

Charge discrimination


beam–test data

average cluster signal

even

ts Good H-He charge discrimination capability.


He

H

magnetic rigidity R = |pc/Z|

all planes

Spatial resolution Critically depends on the signal/noise ratio. Resolution for junction (X, bending) view determines the momentum measurement.


x = (2.77 ± 0.04) m

y = (13.1 ± 0.2) m

Best spatial resolution obtained with non-linear η algorithm for normally incident MIP.

Resolution measurement and sensor alignment done at the last beam test of the flight model with protons of known energies (CERN SPS, 2003).

Whole-tracker alignment checked with cosmic rays collected at ground level during final qualification tests (INFN Rome “Tor Vergata” laboratories, 2005).

In flight: alignment parameters will be checked with high-energy electrons after collecting a sufficient statistical sample (at least 3 months of data taking).

Beam-test data - orthogonally incident MIP

Momentum resolution Measured at beam test with protons of known momentum (CERN SPS, 2003). In flight cross-check with E

measured by calorimeterfor high-energy electrons.


MDR ~ 1 TVmult. scatt. spat. resol. X

magnetic rigidity R = |pc/Z|magnetic deflection η = 1/R = |Z/pc|


Flight data:10 GV

electronwith electr. shower


Flight data:1.56 GVpositron

with electr. shower


Flight data:36 GV proton

with hadronic shower


Flight data:18 GV

antiprotonwithout shower


Flight data:9.7 GV

He nucleuswithout shower

Conclusions

PAMELA is taking data since 11 July 2006.• Up to now >900 Gbyte of data downlinked to ground.• Acquired ~ 90 · 106 events.• Apparatus operating also within radiation belts (SAA).

Magnetic spectrometer on-flight performances are nominal.

Data processing and analysis tools have been developed and used; they are now being finalized.

Next step: systematic data analysis.• Precise determination of detector characteristics.• Application to physics research items.


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Sergio Ricciarini ~ INFN Firenze on behalf of PAMELA collaboration Vertex 2006 15 th International...

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