Multiphoton Excitation Techniques in Combustion Diagnostics

Goldsmith, J. E. M.

doi:10.1557/proc-117-193

MRS Proc.

1988

DOI: 10.1557/proc-117-193

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Multiphoton Excitation Techniques in Combustion Diagnostics

J. E. M. Goldsmith

Abstract: Multiphoton excitation provides spectroscopic access to several species that are very important in flame studies, but that cannot be detected in combustion environments using conventional optical techniques. This paper describes applications of multiphoton excitation techniques for detecting such species in combustion environments, with an emphasis placed on measurements of atomic hydrogen in flames.

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1990

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Cited by 2 publications

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A shock tube with tunable, pulsed laser-based diagnostics

Gray

1990

Review of Scientific Instruments

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This article describes a unique shock tube that is interfaced with a short-pulse, Nd:YAG-pumped, tunable dye-laser system to provide real-time information on transient chemical species. The tube’s internal bore (38.1-mm-diam) accomodates 18 optical diagnostic ports. Pressure-driven shock waves are generated in a double-diaphragm driver section and are timed in the driven section by HeNe laser schlieren detectors. Incident shock speeds range between 1000 and 1500 m/s and are reproducible to ±5 m/s. Individual pulses from the laser and the gate for a photodiode array detector are synchronized with the arrival of shock fronts at the viewing station. Laser-induced fluorescence (LIF) imaging experiments demonstrate the diagnostic power of the new apparatus. One-dimensional (1D) LIF images are recorded in shocked mixtures of ethane, oxygen, and argon by propagating the tunable laser beam along the shock tube’s axis and collecting fluorescence from the OH radical on the 1D detector. The detection sensitivity limit for OH by LIF in this shock tube is approximately 4×1011 radicals/cm3 (0.1 ppm).

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A shock tube with tunable, pulsed laser-based diagnostics

Gray

1990

Review of Scientific Instruments

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show abstract

Investigation of simultaneous two-photon H and single photon OH excitation in flames using a single dye laser

Goldsmith

1990

Appl. Opt.

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Multiphoton Excitation Techniques in Combustion Diagnostics

Cited by 2 publications

References 25 publications

A shock tube with tunable, pulsed laser-based diagnostics

A shock tube with tunable, pulsed laser-based diagnostics

Investigation of simultaneous two-photon H and single photon OH excitation in flames using a single dye laser

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