Proton induced radiation damage studies on plastic scintillators for the Tile calorimeter of the atlas detector
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- Figure 2-3: Diagram depicting the ATLAS calorimeter regions. 2.2.1. The Barrel regions
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2.2.
Plastic scintillators in the Tile Calorimeter The Tile Calorimeter [7] (TileCal) is the hadronic calorimeter of ATLAS [5]. It is a sampling calorimeter, using steel as the absorber medium and scintillator tiles as the active medium. It is responsible for measuring the energy and tracks of hadrons, taus and jets and was designed to contain all hadronic showers developing from the p-p collisions. It also contributes to the reconstruction of missing transverse energy. A zoomed view into the Calorimeter region of the ATLAS detector is shown Figure 2-3. Figure 2-3: Diagram depicting the ATLAS calorimeter regions. 2.2.1. The Barrel regions The TileCal consists of a central long barrel (LB) flanked on either side by extended barrels (EB). Each barrel consists of 64 modules stacked azimuthally, resulting in a cylindrical structure of inner radiu s 2.23 m and outer radius 4.23 m. The LB modules cover the region 0 < |𝜂| < 0.8 , whilst the EB modules cover the region 0.8 < |𝜂| < 1.7 . 9 Each module consists of a matrix of 3 mm thick scintillator t iles sandwiched between 4 mm thick steel plates arranged perpendicular to the beam pipe. The scintillator tiles are arranged in 11 rows and vary in size. As a high energy hadron passes through the tile modules, it interacts with the atomic nuclei of the steel absorber, to produce a shower of lower energy particles. These interact with the scintillator tiles which absorb energy from the incoming particles and fluoresce to emit light. The scintillation light is collected by wavelength shifting (WLS) optical fibers coupled along two of the exposed tile edges. Currently, Y11 fibers obtained from Kuraray are employed. The fibers are arran ged in plastic profiles to ensure contact with individual tiles. Tiles are grouped into readout cells and the fibers of these are bundled together in Lucite tubes. The cells are segmented into three longitudinal layers, (A, BC and D) which are approximately 1.4, 4.0 and 1.8 interaction lengths thick respectively at 𝜂 = 0 . The cells are numbered according to the pseudorapidity range that it covers, with A and BC cells numbered in pseudorapid ity intervals of 0.1 and D cells in intervals of 0.2 [8]. The cell segmentation for the LB and EB modules is shown in Figure 2-5. An LB module contains 337 scintillator tiles per row, leading to a total of 3377 tiles. An EB module contains 1591 scintillating tiles. The fiber bundles are coupled to photomultiplier tubes (PMT), and light detected by the PMT’s generate a signal. Tiles are wrapped in Tyvek paper and fibers are aluminized on the ends which are not coupled to the PMT’s, in order to maximise the amount of light collected. Each cell is read out by two PMT’s, which detect the light from each side of the module. This is done for redundancy and to ensure special uniformity. The signal generated by the PMT’s is then processed with readout electronics housed in the same steel girder as the PMT’s. These then digitize the data which can be analysed thereafter [9]. Figure 2-4 shows a schematic of a TileCal barrel module. |