Abstract
The most probable scenario for the development of experimental high-energy physics in the next 50 years is the creation of a family of Future Circular Colliders (FCC) at CERN, a Circular Electron–Positron Collider at China, and a Future Electron-Ion Collider at Brookhaven (USA), which continue the Large Hadron Collider (LHC) scientific program within the framework of the Standard Model and beyond it. The first generation of colliders to be put into operation will utilize the electron beam as one of the colliding species to provide precise mass spectroscopy in a wide energy range. Similarly to the measurements at the high luminosity phase of the LHC operation, the most important property of the detectors to be used in the experimental setup is a combination of the short response of the detectors and their high time resolution. The radiation tolerance to a harsh irradiation environment remains mandatory but not the main factor of the collider’s experiments using electronic beams. A short response in combination with high time resolution ensures minimization of the influence of the pile-up and spill-over effects at the high frequency of collisions (higher than 50 MGz). The radiation hardness of the materials maintains the long-term high accuracy of the detector calibration. This paper discusses the prospects for using modern inorganic scintillation materials for calorimetric detectors at future colliders.
Highlights
A number of scintillation materials have been developed; only few of them are widely used for the construction of detectors in high-energy physics experiments [1, 2], the reason for this being the need to combine in one material several key properties, namely, high den
A systematic study of the radiation effects in inorganic crystalline scintillation materials [4,5,6,7,8,9,10,11,12] resulted in the development of several families of irradiation-tolerant to different kinds of irradiation Ce doped materials, namely, aluminates and gallates with garnet structure, and oxyorthosilicates
These materials demonstrate a combination of spectacular scintillation properties, the high light yield, fast scintillation kinetics, and chemical and mechanical stability, which makes them perfect candidates for a number of applications in HEP experiments
Summary
A number of scintillation materials have been developed; only few of them are widely used for the construction of detectors in high-energy physics experiments [1, 2], the reason for this being the need to combine in one material several key properties, namely, high den-. A systematic study of the radiation effects in inorganic crystalline scintillation materials [4,5,6,7,8,9,10,11,12] resulted in the development of several families of irradiation-tolerant to different kinds of irradiation Ce doped materials, namely, aluminates and gallates with garnet structure, and oxyorthosilicates.
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