Containerless photothermal spectroscopy using photorefractive interferometric detection

Photothermal spectroscopy of gases is explored using optical detection of the thermal expansion of the gas through the use of photorefractive dynamic holography. The photorefractive effect in bismuth silicon oxide is exploited to demodulate the optical phase shift of a signal beam traversing a gaseo...

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Bibliographic Details
Published inOptical Engineering Vol. 41; no. 7; pp. 1688 - 1695
Main Authors Schley, Robert S, Telschow, Ken L
Format Journal Article
LanguageEnglish
Published United States 01.07.2002
Subjects
ABSORPTION
ACOUSTICS
BISMUTH
BUFFERS
DETECTION
EXCITATION
GASES
GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE
HOLOGRAPHY
HYDROFLUORIC ACID
interferometry
MIXTURES
NITROGEN
opitical detection
PHASE SHIFT
photoacoustic
photorefractive
photothermal
photothermal spectroscopy
SILICON OXIDES
SPECTROSCOPY
THERMAL EXPANSION
WATER VAPOR
WAVELENGTHS
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Summary:Photothermal spectroscopy of gases is explored using optical detection of the thermal expansion of the gas through the use of photorefractive dynamic holography. The photorefractive effect in bismuth silicon oxide is exploited to demodulate the optical phase shift of a signal beam traversing a gaseous environment and coincident with a tunable chopped excitation beam. Molecular absorption at the excitation wavelength produces heat that causes local expansion and subsequent acoustic wave radiation. A test cell, although unnecessary for this technique that can perform measurements in a containerless or open environment, was used to provide known gas mixtures to be tested. A model of the photoacoustic absorption and the optical phase detection process has been developed at low frequencies, where the process can be approximated as photothermal expansion. Measurement and modeling results are presented that illustrate the ability of the method to detect water vapor and hydrogen fluoride concentrations in nitrogen atmosphere backgrounds near 800 nm, currently producing sensitivities in the 20 to 1000 ppm range. The effects of buffer gas concentrations, excitation frequencies, and the ability to measure temporal changes of trace gas concentrations are illustrated. Limitations of the technique and methods for extending to ppb sensitivities with infrared excitation are also discussed. ©
Bibliography:USDOE
DE-AC07-99ID-13727
INEEL/JOU-01-01136
ISSN:0091-3286
1560-2303
DOI:10.1117/1.1483311