Thermophysical properties of lithium thiogallate that are important for optical applications

Lithium thiogallate LiGaS 2 is one of the most common nonlinear crystals for mid-IR due to its extreme beam strength and wide transparency range; however, its thermophysical properties have not yet been practically studied. Large crystals of high optical quality are grown. DTA revealed features at 1...

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Bibliographic Details
Published in:RSC advances 2021-12, Vol.11 (62), p.39177-39187
Main Authors: Kurus, Alexey, Yelisseyev, Alexander, Lobanov, Sergei, Plyusnin, Pavel, Molokeev, Maxim, Solovyev, Leonid, Samoshkin, Dmitry, Stankus, Sergei, Melnikova, Svetlana, Isaenko, Lyudmila
Format: Article
Language:English
Subjects:
Chemistry
Crystals
Current carriers
Differential thermal analysis
Excitons
Lithium
Low temperature
Melting points
Optical filters
Optical properties
Photoluminescence
Refractivity
Room temperature
Thermal conductivity
Thermoluminescence
Thermophysical properties
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Summary:Lithium thiogallate LiGaS 2 is one of the most common nonlinear crystals for mid-IR due to its extreme beam strength and wide transparency range; however, its thermophysical properties have not yet been practically studied. Large crystals of high optical quality are grown. DTA revealed features at 1224 K below melting point (1304 K) that are associated with the oxygen containing compounds of the LiGaO 2− x S x type. The thermal conductivity of LiGaS 2 (about 10.05 W (m −1 K −1 )) and band gap value (3.93 eV at 300 K) are found to be the highest in the LiBC 2 family. Isotropic points in the dispersion characteristics for the refractive index are found and LiGaS 2 -based narrow-band optical filters, smoothly tunable with temperature changes, are demonstrated. Intense blue photoluminescence of anionic vacancies V S is observed at room temperature after annealing LiGaS 2 in vacuum, whereas orange low-temperature emission is related to self-trapped excitons. When LiGaS 2 crystals are heated, spontaneous luminescence (pyroluminescence) takes place, or thermoluminescence after preliminary UV excitation; the parameters of traps of charge carriers are estimated. The obtained data confirm the high optical stability of this material and open up prospects for the creation of new optical devices based on LiGaS 2 . LiGaS 2 crystals are grown, and the high thermal conductivity is established. Analysis of temperature dependences of various properties reveals side phases, and isotropic points in birefringence, photo-, thermo-, and pyroluminescence.
ISSN:2046-2069
2046-2069
DOI:10.1039/d1ra05698k