Two-photon lidar technique for remote sensing of atomic oxygen

T. J. McIlrath; R. Hudson; A. Aikin; T. D. Wilkerson

doi:10.1364/AO.18.000316

Applied Optics
Vol. 18,
Issue 3,
pp. 316-319
(1979)
•https://doi.org/10.1364/AO.18.000316

Two-photon lidar technique for remote sensing of atomic oxygen

T. J. McIlrath, R. Hudson, A. Aikin, and T. D. Wilkerson

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T. J. McIlrath, R. Hudson, A. Aikin, and T. D. Wilkerson, "Two-photon lidar technique for remote sensing of atomic oxygen," Appl. Opt. 18, 316-319 (1979)

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Abstract

A technique is proposed for remote sensing of atomic oxygen by laser excitation of a two-photon transition. Excitation at 2256 Å and subsequent fluorescence at 8447 Å allow probing of the mesosphere and lower thermosphere without interference by absorption. The two-photon excitation rate is calculated, and its dependence on laser power, duration, and linewidth is discussed. Values are given for remote sensing from a spacecraft at 200 km ranging down to 80 km with 1-km range resolution. Accuracies of better than 10% are expected with a 1 J, a 20-psec excitation pulse, and a 1-m² collecting telescope.

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Alt.	Density of atomic oxygen	Photon return	Fractional fluctuation 1/N (× 10⁻²)	Photoelectron fluctuations for 10% efficiency system 1/(0.1N)^1/2 × 10⁻²
180	5.E + 9	3820	1.6	5.1
160	1.E + 10	1710	2.4	7.6
140	2.E + 10	1300	2.8	8.0
120	7.6E + 10	2310	2.1	6.6
100	5.E + 11	7970	1.1	3.5
80	8.5E + 10	770	3.6	11

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Applied Optics