Theoretical Demonstration of the Interest of Using Porous Germanium to Fabricate Multilayer Vertical Optical Structures for the Detection of SF[sub.6] Gas in the Mid-Infrared

Theoretical Demonstration of the Interest of Using Porous Germanium to Fabricate Multilayer Vertical Optical Structures for the Detection of SF[sub.6] Gas in the Mid-Infrared

Porous germanium is a promising material for sensing applications in the mid-infrared wavelength range due to its biocompatibility, large internal surface area, open pores network and widely tunable refractive index, as well as its large spectral transparency window ranging from 2 to 15 μm. Multilay...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Vol. 22; no. 3
Main Authors: Zegadi, Rami, Lorrain, Nathalie, Meziani, Sofiane, Dumeige, Yannick, Bodiou, Loїc, Guendouz, Mohammed, Zegadi, Abdelouahab, Charrier, Joël
Format: Journal Article
Language:English
Published: MDPI AG 22-01-2022
MDPI
Subjects:
Engineering Sciences
mid-infrared detection
porous germanium materials
Bragg reflector
optical microcavity
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Summary:Porous germanium is a promising material for sensing applications in the mid-infrared wavelength range due to its biocompatibility, large internal surface area, open pores network and widely tunable refractive index, as well as its large spectral transparency window ranging from 2 to 15 μm. Multilayers, such as Bragg reflectors and microcavities, based on porous germanium material, are designed and their optical spectra are simulated to enable SF[sub.6] gas-sensing applications at a wavelength of 10.55 µm, which corresponds to its major absorption line. The impact of both the number of successive layers and their respective porosity on the multilayer structures reflectance spectrum is investigated while favoring low layer thicknesses and thus the ease of multilayers manufacturing. The suitability of these microcavities for mid-infrared SF[sub.6] gas sensing is then numerically assessed. Using an asymmetrical microcavity porous structure, a sensitivity of 0.01%/ppm and a limit of detection (LOD) around 1 ppb for the SF[sub.6] gas detection are calculated. Thanks to both the porous nature allowing gases to easily infiltrate the overall structure and Ge mid-infrared optical properties, a theoretical detection limit nearly 1000 times lower than the current state of the art is simulated.
Bibliography:PMCID: PMC8839726
ISSN:1424-8220
1424-8220
DOI:10.3390/s22030844