Engineering of Scintillation Materials and Radiation Technologies, 1st ed. 2019
Selected Articles of ISMART2018
Springer Proceedings in Physics Series, Vol. 227

Part 1 Fundamental Studies.- Fast Processes in Scintillators.- Transient phenomena in scintillation materials.- Fluctuations of Track Structure and energy Resolution of Scintillators.- New properties and prospects of Hot Intraband Luminescence for fast timing.- Part 2  Material Science.- Ceramic scintillation materials – approaches, challenges and possibilities.- Disordered garnet structure scintillation materials for novel detectors of ionizing radiation.- Garnet crystal growth in non-precious metal crucibles.- Part 3 Technology and Production.- Towards new production technologies: 3D printing of scintillators.- Enriched ⁴⁰Ca¹⁰⁰MoO₄ single crystalline material for search of neutrinoless double beta decay.- Plastic scintillators with the improved radiation hardness level.- Part 4  Detector Solutions.- Application of scintillation detectors in cosmic experiments.- Neutron cross section measurements with diamond detector.- Investigation of the properties of the heavy scintillating fibers for their potential use in hadron therapy monitoring.- Development of a submillimeter portable gamma-ray imaging detector, based on a GAGG:Ce - silicon photomultiplier array.- Application scintillation comparators for calibration low intense gamma radiation fields by dose rate in the range of 0.03 – 0.1 µSv/h.- Antineutrino Detectors.- Part 5 Instrumentation.- Development of the X-ray security screening systems at ADANI.- Optimization of physico-topological parameters of dual energy X-ray detectors applied in inspection equipment.- Control of organ and tissue doses to patients during Computed Tomograph.- Information Tool for Multifarious Scientific and Practical Research.- Calibration and performance of the CMS electromagnetic calorimeter during the LHC Run II.- Study the applicability of neutron calibration facility for spectrometer calibration as a source of gamma rays with energies to 10 MeV.- Thermal neutron detector based on LaOBr:Ce/LiF.- Specifics of 3D-printed electronics.

 

 

 

Mikhail Korzhik (Korjik) received his diploma in Physics at the Belarus State University in 1981. He got his PhD in 1991 and Doctoral Diploma in 2005 in Nuclear Physics and Optics. Since the beginning of nineties he was deeply involved in research and development of inorganic scintillation materials. He was instrumental in the development of the YAlO₃:Ce technology for low energy gamma-rays detection. An important achievement has been the discovery of  Pr³⁺ doped scintillation media and GdAlO₃:Ce and LuAlO₃:Ce scintillation materials. His study promoted the understanding of scintillation mechanism in many crystals. He took part in the discovery and mass production technology development of the lead tungstate PbWO₄ scintillation crystal for high energy physics application, which resulted in the use of this crystal in two ambitious experiments at LHC, CMS and ALICE and an important contribution to the discovery of the Higgs boson. He is member of the Scientific Advisory Committee of the SCINT cycle of International Conferences dedicated to scintillation materials development.