High-Strength Optical Coatings for Single-Crystal ZnGeP2 by the IBS Method Using Selenide and Oxide Materials

High-Strength Optical Coatings for Single-Crystal ZnGeP2 by the IBS Method Using Selenide and Oxide Materials

The paper presents the results on the development of an optical coating for a single-crystal ZnGeP2 substrate based on a selenide-oxide pair of materials (ZnSe/Al2O3). The obtained coating ensures the operation of OPO in the mid-IR range up to 5 μm wavelengths. The possibility of ZnSe sputtering by...

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Veröffentlicht in:Ceramics 2023-03, Vol.6 (1), p.514-524
Hauptverfasser: Zinovev, Mikhail, Yudin, Nikolay N., Kuznetsov, Vladimir, Podzyvalov, Sergey, Kalsin, Andrey, Slyunko, Elena, Lysenko, Alexey, Vlasov, Denis, Baalbaki, Houssain
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum oxide
AR coatings
Bridgman method
Coatings
ion beam sputtering
Laser damage
Lasers
LIDT
Optical coatings
Optical components
oxides
Protective coatings
Pulse duration
Pulse repetition frequency
Single crystals
Substrates
Yield point
ZnGeP2 single crystal
ZnSe
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Zusammenfassung:The paper presents the results on the development of an optical coating for a single-crystal ZnGeP2 substrate based on a selenide-oxide pair of materials (ZnSe/Al2O3). The obtained coating ensures the operation of OPO in the mid-IR range up to 5 μm wavelengths. The possibility of ZnSe sputtering by the IBS method is shown. The obtained optical coating has a high laser-induced damage threshold (LIDT) value at a 2097 µm wavelength: WoE=3.51 J/cm2 in energy density and WoP= 101 W/cm2 in power density at a 10 KHz pulse repetition frequency and a pulse duration of 35 ns. Thus, it is shown for the first time that the pair of materials ZnSe/Al2O3 can be used for the deposition of optical coatings by the IBS method with high LIDT values for ZnGeP2 optical elements operating in the mid-IR range.
ISSN:2571-6131
2571-6131
DOI:10.3390/ceramics6010030