Pulsed spontaneous Raman scattering technique for luminous environments

A. J. Mulac; W. L. Flower; R. A. Hill; D. P. Aeschliman

doi:10.1364/AO.17.002695

Applied Optics
Vol. 17,
Issue 17,
pp. 2695-2699
(1978)
•https://doi.org/10.1364/AO.17.002695

Pulsed spontaneous Raman scattering technique for luminous environments

A. J. Mulac, W. L. Flower, R. A. Hill, and D. P. Aeschliman

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A. J. Mulac, W. L. Flower, R. A. Hill, and D. P. Aeschliman, "Pulsed spontaneous Raman scattering technique for luminous environments," Appl. Opt. 17, 2695-2699 (1978)

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Abstract

A gated photon counting system, cavity-dumped argon-ion laser, and a multipass retroreflecting light cell have been combined in a system to enhance spontaneous Raman scattering in luminous background situations. Signal-to-background ratio (SBR) has been improved a factor of 450 over a single-pass cw system with cw power equal to the pulsed average power. The improvement attributable to the gating and cavity dumping the laser is a factor of 30. A factor of 15 improvement is due to the retroreflecting light cell. Temperature and density data obtained from N₂Q-branch spectra of a luminous methane–air flame are presented to illustrate the utility of the system. A passband fitting technique is introduced to analyze the data.

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Spectrum	z (mm)	Δt (sec)	Pulsed technique		cw 1 W SBR	ρN₂ (kg/m³)	T (K)		σ_T (K)
Spectrum	z (mm)	Δt (sec)	Signal (counts)	SBR	cw 1 W SBR	ρN₂ (kg/m³)	T (K)		σ_T (K)
a	3	120	25,580	0.95	0.034	0.144		1798	±20
b	9	60	12,676	28.23	1.01	0.115		1888	±16
c	9	60	8787	9.39	0.34	—		1869	±26

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Applied Optics