Proton induced radiation damage studies on plastic scintillators for the Tile calorimeter of the atlas detector
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Introduction Plastic scintillators are organic materials which exhibit the effect of luminescence when interacting with ionising radiation. Incident radiation causes electronic excitations within the scintillator material which then relax back to their ground state through the fluorescence process where emission of light occurs [1]. Since the amount of light emitted is dependent on the energy of the exciting particle, scintillators can be utilized for particle identification and hence play an important role in the field of detector physics. In addition to detection of ionising particles, plastic scintillators can be used for neutron identification since neutrons can elastically scatter with hydrogen, resulting in proton recoils. Plastic scintillators have been used for a vast number of applications. They are employed in radiation dosimetry in medical physics and in cosmic detection systems like the Alpha Magnetic Spectrometer (AMS) in the field of astrophysics, but it is their applications to high energy detector system s that are of interest to this study. 1.1. Motivation The ATLAS detector (A Torroidal LHC Apparatus), is a multipurpose detector involved in the search for new particles through the reconstruction of high energy proton-proton (p-p) collisions generated at the Large Hadron Collider (LHC) of CERN. During the data taking period of 2009-2012 (Run1), the LHC generated p-p collisions at energies of up to √𝑠 = 7 TeV , and in 2012, ATLAS announced the discovery of a boson consistent with that of the Higg’s boson. This discovery lends support to the idea of the existence of a Higg’s field which plays a crucial role in explaining how particles gain mass . [2]. The Tile calorimeter of ATLAS contains tiles of plastic scintillators which provide the key detection mechanism for detecting hadronic jets and showers of quarks and gluons that result from the proton-proton collisions. 2 Plastic scintillators are ideal for use in the Tile calorimeter since their properties of high light output and high optical transmission ensure that good resolution in measurements can be achieved. Their fast rise and decay times are ideal since fast timing responses are required [1]. Furthermore, plastic scintillators are easier to manufacture as compared to inorganic crystals which require special growi ng methods that can prove to be costly. As a result, plastic scintillators are more cost effective for covering large detector areas [3]. The main drawback of plastic scintillators however, is their susceptibility to radiation damage. When charged particles pass through a scintillator, they dissipate their energy to the scintillator molecules via ionization losses. This generates a large number of electronic excitations along the path of the particle which may fluoresce to emit light. Ionization may also lead to the formation of ions and free radicals which can affect both the structural and optical properties of the scintillators. Any processes occurring that reduce the intensity of fluorescence emission are regarded as quenching processes. Radiation damage may lead to additional quenching of the scintillation light emitted by a scintillator [1]. This introduces an error into the data acquired by the detector, and if not accounted for correctly, can compromise the credibility of the detector accuracy. As the amount of radiation exposure is increased, these light losses may become more significant. Therefore, plastic scintillators that are employed need to exhibit a certain degree of tolerance against radiation damage . Presently, the LHC is undertaking several upgrades in order to broaden the scope of physics that can be studied. In 2015, Run2 began with the first beams of 13 TeV being reached. In addition, the LHC plans to increase the luminosity (number of proton collisions per bunch crossing) by a factor of 10 beyond its design value after 2022. These upgrades will significantly impact the radiation environment that scintillators are exposed to. Several new collider and detection systems are also presently under discussion with plans to commence within the next 20 ye ars. Some of these plan to run at much higher energy and luminosities [4]. 3 As such, a need has arisen for a study into how sustai nable current available scintillators used in high energy physics detectors are. Furthermore, the Tile Calorimeter has implemented a series of upgrades in order to ensure that the detector performance can be sustained for several years to come. Part of phase two of this upgrade will be implemented in 2018 where scintillators from the Gap region of the Tile Cal will be replaced with more radiation tolerant plastics. This study, therefore, investigates the radiation damage undergone by polystyrene and polyvinyl toluene based plastic scintillators after exposure to proton irradiation. Proton irradiation was decided upon since the Tile calorimeter interacts with hadrons. In addition, the proton carries charge and would therefore account for the coulomb interactions that occur in collisions betwee n charged particles. The facilities for proton irradiation were readily available for the study, i.e. the 6 MV Tandem accelerator of iThemba LABS. Scintillators obtained from Eljen Technologies, Saint Gobain Crysta ls as well as those presently used by the Tile Calorimeter of ATLAS have been investigated. This study forms part of a larger investigative effort that will be used for choosing the scintillator replacement candidate for the 2018 upgrade of the Tile Calorimeter. Yüklə 8,51 Mb. Dostları ilə paylaş:
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