Doctoral Dissertations
Date of Award
5-2024
Degree Type
Dissertation
Degree Name
Doctor of Philosophy
Major
Materials Science and Engineering
Major Professor
Mariya Zhuravleva
Committee Members
Charles L. Melcher, Maciej Kapusta, Claudia Rawn, Jason Hayward
Abstract
Cs2ZnCl4 [dicesium zinc tetrachloride] and Cs3ZnCl5 [tricesium zinc pentachloride] are relatively new scintillator materials that appear to be promising for use in fast-timing radiation detection applications owing to their 1 to 2 nanosecond decay times. Moreover, they offer several advantages over the state-of-the-art ultrafast inorganic scintillator BaF2 [barium fluoride]. To fully realize the potential of these novel materials, growth of crystals having improved optical quality must be demonstrated. The mechanism responsible for the ultrafast decay times, core valence luminescence (CVL), in cesium zinc chloride crystals can also be observed in other compounds containing CsCl [cesium chloride]; however, the list of possible materials exhibiting this type of luminescence has not yet been exhausted.
In this dissertation, Cs2ZnCl4 and Cs3ZnCl5 are first investigated with special attention paid to optimizing synthesis methods and crystal growth parameters to enable growth of large crack-free crystals. We have found that higher light yields than reported in literature can be achieved as a result of superior optical transparency. Additionally, Cs2ZnCl4 is successfully grown up to 38 mm in diameter without significant cracking.
Next, we report the discovery of two new scintillators, Cs2MgCl4 [dicesium magnesium tetrachloride] and Cs3MgCl5 [tricesium magnesium pentachloride], that belong to the same structural families as the Zn-containing compounds. The scintillation mechanism is confirmed to be CVL, and similar benefits regarding light yield, emission wavelengths, and single-component decay times are observed as with Cs2ZnCl4 and Cs3ZnCl5.
Effects of doping or mixing between Mg2+ and Zn2+ in these systems are explored as a strategy for improving performance. It is found that light yields of CsMgCl3 [cesium magnesium trichloride], Cs2MgCl4, and Cs3MgCl5 can be significantly enhanced when doped with Zn2+, directly impacting their timing performance. More importantly, these findings open up possibilities for a new class of bright CVL materials to be discovered moving forward. Possible mechanisms for this impurity-enhanced CVL are discussed.
Recommended Citation
Rutstrom, Daniel, "Development of Novel Cesium Chloride-based Ultrafast Inorganic Scintillators for Fast Timing Radiation Detection Applications. " PhD diss., University of Tennessee, 2024.
https://trace.tennessee.edu/utk_graddiss/10161