M. Caria

Electron, pion and multiparticle detection with a lead/scintillating-fiber calorimeter

Abstract We report on the performance of a fine-grained 13-ton lead/scintillating-fiber calorimeter, in particular on its response to electrons, pions and multiparticles (reaction products from pions interacting in a target upstream of the detector). The detector signals were studied for particles in the energy range 5–150 GeV. The energy resolution was measured to be 12.9% √E for electrons, plus a constant term dependent on the angle θ Z between the particles direction and the fiber axis. This term, which is 1.2% for θ z = 3°, is shown to be due to anomalous sampling in the early shower stage. It is greatly reduced when only electrons entering the detector in the lead are considered. A 1.7 X 0 thick preshower detector, installed 12 cm in front of the calorimeter, only affected the signal linearity for electrons at low energy. The effect on the energy resolution was negligible. Single pions were detected with an energy resolution of ∼ 30%/√ E plus a constant term, which turned out to be mainly due to the effects of light attenuation in the fibers. Knowing the impact point of the particles, these effects could be efficiently removed for single pions. For jets (multiparticles), the effects of light attenuation are much less important, leading to considerably better on-line energy resolutions. The e π signal ratio was measured to range from 1.03 at 80 GeV to 1.10 at 5 GeV, for a detector with an effective radius of 49 cm. After correcting for the instrumental effects, we found the intrinsic e h value of this detector (with our particular choice of fibers and sampling fraction) to be 1.15±0.02. Detailed results are given on the detector performance (energy resolution, e π signal ratio, e/jet signal ratio) as a function of the lateral detector size and as a function of the jet multiplicity.

Results of prototype studies for a spaghetti calorimeter

In the framework of the LAA project, prototypes for a new type of calorimeter, intended for the detection of both electromagnetic (e.m.) and hadronic showers, muons and missing energy (e.g. neutrinos) at high-luminosity multi-TeV pp colliders, were tested. The detector consists of scintillating plastic fibres embedded in a lead matrix at a volume ratio 1:4, such as to achieve compensation. The optimization of the construction of the detector modules is described, as well as the performance concerning e.m. shower and muon detection and e/π separation. We used electron, pion and muon beams in the energy range 10–150 GeV for this purpose. For the energy resolution of electrons we found 13%/trE, with a constant term of 1%. The signal uniformity was better than 3% over the total surface of projective modules. The signal linearity for e.m. shower detection was better than 1%, and the e/π separation was better than 5 × 10−4 for isolated particles. Channeling effects are negligible, provided that the angle between the incoming particles and the fibre axis is larger than 2°.

Electron-pion discrimination with a scintillating fiber calorimeter

Abstract We report on an experimental study of a variety of techniques for discriminating between (isolated) electrons and pions in a lead and scintillating fiber calorimeter without longitudinal segmentation. Using information from the lateral shower development, from a pre-shower detector, from the time structure of the signals, or from a combination of these we measure pion rejection factors of up to several thousand while maintaining electron efficiencies of 95% or higher.

Localizing particles showering in a Spaghetti Calorimeter

We report on the performance of a fine-grained 13-ton compensating lead/scintillating-fiber calorimeter, and in particular on its capability of localizing the particles that produce showers in it. The RMS position resolution was found to be 1.7 mm for electromagnetic showers and 5.1 mm for hadronic showers at 80 GeV, averaged over a tower with an effective radius of 39 mm. Pion-pion separation through analysis of the energy deposit pattern was achieved in more than 95% of the cases for distances down to 8 cm at 80 GeV. Because of the good lateral position resolution, detailed information on the longitudinal shower development could be obtained, with the help of tracking information, when single particles entered the (longitudinally unsegmented) detector at a small angle with respect to the fiber axis. This information made it possible to eliminate the effects of light attenuation in the fibers on the hadronic energy resolution and allowed e/π separation at the 10−4 level.

Gallium arsenide photodetectors for imaging in the far ultraviolet region

The aim of the present work is to systematically investigate the response and stability of commercial GaAs devices in the 200–400 nm UV range with a view to establishing their potentiality in imaging devices. The irradiation results of GaAs detectors with various geometries are presented and discussed. The detectors were reverse biased in fully depleted condition and in partially depleted condition (5 V reverse bias) in order to investigate the possibilities of integration with the standard bias values of read-out-integrated circuits. The results show that fabrication technology for nondedicated devices is still immature.

AUTORADIOGRAPHY WITH SILICON STRIP DETECTORS

A digital autoradiography system based on double sided silicon strip detectors (1.6 × 1.6 mm2 active surface with 100 μm pitch) has been developed and successfully tested with beta-emitting tracers. It is shown here that the system is able to perform imaging of organic material with specific sensitivity as small as 0.002 nCi/mm2, and to record activity measurements with good linearity in the range 0.002–20 nCi/mm2. Autoradiographic images of clusters of mammary cells marked with ortho-(32P)phosphate, obtained with an exposure time of about 10 min are presented.

On muon production and other leakage aspects of pion absorption in a lead/scintillating-fiber calorimeter

Abstract We report on an experimental study of longitudinal leakage phenomena in hadronic shower development. Pions in the energy range of 10–150 GeV were sent into a lead/scintillating-fiber calorimeter with a thickness of 9.6 nuclear interaction lengths. The average fraction of the energy leaking out at the back of this calorimeter ranges from 0.04% at 10 GeV to 0.4% at 150 GeV. This leakage has a very small effect on the hadronic energy resolution. We measured the probability of the creation of escaping muons in the shower development process. This probability ranges from 0.2% at 10 GeV to 2.1% at 150 GeV. Assuming that these muons are produced from π- or K-decay, we find an exponentially decaying muon spectrum with a typical momentum of 2.8 GeV/ c , at 80 GeV incident energy. Also the rates at which hadrons and soft neutrons escape from the calorimeter are measured. Within the acceptance of the leakage calorimeter, neutrons are observed about 10 times as often as muons. Escaping hadrons dominate muons for shower energies above 20 GeV. The experiments were performed at CERN in the framework of the LAA project.

The design of a system for coloured digital radiology with VLSI circuits and GaAs pixel detectors

AbstractWedescribethedesignofadigitalradiologysystemwithGaAspixeldetectors,basedontheenergyselectionofthenonabsorbedX-ray spectrum.We present ageneral layout; we show that simulationand experimentaldatacorroboratetheidea for the feasibility of the system. ( 1998 Elsevier Science B.V. All rights reserved. 1. IntroductionTheuseof GaAsasahigh-eƒciencyX-rayimag-ing detector is now well known [1].An idea for a novel digital radiology device withinherent high spatial and energy resolution hasbeen proposed [2]. It is based on a GaAs pixeldetector and two custom-made VLSI electroniccircuits which process each photon pulse and clas-sify it according to its energy.The circuits store the counting and the energyinformation, allowing the acquisition of coloured X-ray images. The artiÞcial elaboration of colourcan be performedon line in a scale proportionaltotheenergyofthedetectedphoton.Thescaleresolu-tionwillbelimitedbytheelectroniccircuitsdesign.The method,generallyapplicable,has beenillus-trated before [3]. Here we describe the design fora digital imaging system with an X-ray source,a GaAs pixel detector and the VLSI circuits. Thepaperconcentratesonthegenerallayoutinarealis-tic conÞguration. We address the compromises be-tween the performances of the system, versus thefabrication technologies risks and the costs.WehaveatpresentaÞrstversionofthedetectorswith 32 pixels and the new chip with 8 energyintervals.We show data and compare with the simulationproving that the design idea is well based.2. The basic principleIn radiology, the use of the energy and count-ing information is performed simultaneously in

Current trends on design and assembly of pixel detector systems in biomedicine and high-energy physics

Abstract The design and assembly of an integrated system made of pixel sensors as sensitive elements combined with read-out electronics and connecting cables or alternative connecting structures, is discussed. The new trends are summarised and critically evaluated. It is shown that many problems are common to High-Energy Physics and Biomedical devices and that this cross-interaction is profitable. Technological choices on new highly integrated modules are presented, with the first successful cases and the risks of failure.

Large-series test of limited streamer tubes

Abstract A detailed description of the setup and of the procedure used for the large-scale quality test of the 154 560 limited streamer tubes which compose the CHARM II calorimeter is given. The size of the project has imposed the adoption of a procedure that is simple and fast, yet dependable. The high reliability of the test has been proven by the stability of the system after 20 months of continuous operation.