Decay Kinetics of CeF3 under VUV and X-ray Synchrotron Radiation

Characteristic dimensions and evolution times of regions of secondary electronic excitations created by the interaction of ionizing radiation with matter cannot be measured directly. At the same time these are essential parameters both for engineering of nanostructured composite materials defining o...

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Published inSymmetry (Basel) Vol. 12; no. 6; p. 914
Main Authors Kamenskikh, Irina, Tishchenko, Evgeny, Kirm, Marco, Omelkov, Sergey, Belsky, Andrei, Vasil’ev, Andrey
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2020
MDPI
Subjects
Atomic Physics
CeF3 crystals
Composite materials
Crystal structure
Decay
Diffusion length
Diffusion rate
Dipole interactions
electronic excitations
Energy
Excitons
Experiments
interaction of excitations
Ionizing radiation
Kinetics
Luminescence
luminescence kinetics
Nanoparticles
Photons
Physics
Scintillation counters
Sensors
Spectrum analysis
Synchrotron radiation
Thickness
X-rays
Sweden
CeF 3 crystals
electronic excitations
luminescence kinetics
interaction of excitations
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Summary:Characteristic dimensions and evolution times of regions of secondary electronic excitations created by the interaction of ionizing radiation with matter cannot be measured directly. At the same time these are essential parameters both for engineering of nanostructured composite materials defining optimal layer thickness and nanoparticles radii and for the development of optimized scintillators. The paper demonstrates how such spatial and temporal data can be extracted from luminescence decay kinetics excited by vacuum ultraviolet (VUV) and X-ray photons at modern sources of synchrotron radiation MAX IV and PETRA III. Specific features of energy-band structure of self-activated crystal CeF3 are discussed, and its potential for a super-fast detection of ionizing radiation evaluated. Diffusion-controlled dipole–dipole interaction of Frenkel excitons is demonstrated to account well for the luminescence non-exponential decay kinetics providing information on the scales of excited regions created by photons of different energy. For 20 eV photons the radius of excited regions is estimated to be 10 nm, and for 200 eV photons it increases to 18 nm. Effective radius of excited regions of complicated shape created by 19 keV is as large as 80 nm and the diffusion length of Frenkel excitons over radiative time is 14 nm.
ISSN:2073-8994
2073-8994
DOI:10.3390/sym12060914