Investigation of silver gallium sulfide and silver gallium selenide for upconversion beyond 10 µm

Peter Tidemand-Lichtenberg; Rasmus Lyngbye Pedersen; Ludovica Appignani; Christian Pedersen

doi:10.1364/OL.537797

Investigation of silver gallium sulfide and silver gallium selenide for upconversion beyond 10 µm

Peter Tidemand-Lichtenberg, Rasmus Lyngbye Pedersen, Ludovica Appignani, Christian Pedersen

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Abstract

This paper investigates silver gallium selenide (AGSe) as a promising alternative to silver gallium sulfide (AGS) for upconversion detection beyond 10 µm. AGSe offers a wide transparency range extending to ∼20 µm, making it a candidate for upconversion detection in the challenging 10 to 20 µm range. Beyond 12 µm, AGS is not an option due to high absorption. An experimental setup is implemented for crystal comparison in the 10 to 12 µm range, based on a tunable quantum cascade laser (QCL). Phase matching constraints in AGSe required an 1880 nm mixing laser, whereas AGS was conveniently implemented with a 1064 nm mixing laser. Detection of the upconverted signal is consequently based on InGaAs (for AGSe) and Si detectors (for AGS), respectively. Results show that AGSe offers higher upconversion efficiency and superior phase matching properties, making it a promising crystal for long-wavelength infrared (IR) detection.

Original language	English
Journal	Optics Letters
Volume	49
Issue number	23
Pages (from-to)	6868-6871
Number of pages	4
ISSN	0146-9592
DOIs	https://doi.org/10.1364/OL.537797
Publication status	Published - 1 Dec 2024

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title = "Investigation of silver gallium sulfide and silver gallium selenide for upconversion beyond 10 µm",

abstract = "This paper investigates silver gallium selenide (AGSe) as a promising alternative to silver gallium sulfide (AGS) for upconversion detection beyond 10 µm. AGSe offers a wide transparency range extending to ∼20 µm, making it a candidate for upconversion detection in the challenging 10 to 20 µm range. Beyond 12 µm, AGS is not an option due to high absorption. An experimental setup is implemented for crystal comparison in the 10 to 12 µm range, based on a tunable quantum cascade laser (QCL). Phase matching constraints in AGSe required an 1880 nm mixing laser, whereas AGS was conveniently implemented with a 1064 nm mixing laser. Detection of the upconverted signal is consequently based on InGaAs (for AGSe) and Si detectors (for AGS), respectively. Results show that AGSe offers higher upconversion efficiency and superior phase matching properties, making it a promising crystal for long-wavelength infrared (IR) detection.",

author = "Peter Tidemand-Lichtenberg and Pedersen, {Rasmus Lyngbye} and Ludovica Appignani and Christian Pedersen",

year = "2024",

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T1 - Investigation of silver gallium sulfide and silver gallium selenide for upconversion beyond 10 µm

AU - Tidemand-Lichtenberg, Peter

AU - Pedersen, Rasmus Lyngbye

AU - Appignani, Ludovica

AU - Pedersen, Christian

PY - 2024/12/1

Y1 - 2024/12/1

N2 - This paper investigates silver gallium selenide (AGSe) as a promising alternative to silver gallium sulfide (AGS) for upconversion detection beyond 10 µm. AGSe offers a wide transparency range extending to ∼20 µm, making it a candidate for upconversion detection in the challenging 10 to 20 µm range. Beyond 12 µm, AGS is not an option due to high absorption. An experimental setup is implemented for crystal comparison in the 10 to 12 µm range, based on a tunable quantum cascade laser (QCL). Phase matching constraints in AGSe required an 1880 nm mixing laser, whereas AGS was conveniently implemented with a 1064 nm mixing laser. Detection of the upconverted signal is consequently based on InGaAs (for AGSe) and Si detectors (for AGS), respectively. Results show that AGSe offers higher upconversion efficiency and superior phase matching properties, making it a promising crystal for long-wavelength infrared (IR) detection.

AB - This paper investigates silver gallium selenide (AGSe) as a promising alternative to silver gallium sulfide (AGS) for upconversion detection beyond 10 µm. AGSe offers a wide transparency range extending to ∼20 µm, making it a candidate for upconversion detection in the challenging 10 to 20 µm range. Beyond 12 µm, AGS is not an option due to high absorption. An experimental setup is implemented for crystal comparison in the 10 to 12 µm range, based on a tunable quantum cascade laser (QCL). Phase matching constraints in AGSe required an 1880 nm mixing laser, whereas AGS was conveniently implemented with a 1064 nm mixing laser. Detection of the upconverted signal is consequently based on InGaAs (for AGSe) and Si detectors (for AGS), respectively. Results show that AGSe offers higher upconversion efficiency and superior phase matching properties, making it a promising crystal for long-wavelength infrared (IR) detection.

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DO - 10.1364/OL.537797

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JO - Optics Letters

JF - Optics Letters

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Investigation of silver gallium sulfide and silver gallium selenide for upconversion beyond 10 µm

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