Interferometric atmospheric refractive-index environmental monitor

Jacques E. Ludman; Jacques J. Ludman; Heidi Callahan; H. John Caulfield; David Watt; John L. Sampson; John Robinson; Seth Davis; Arlon Hunt

doi:10.1364/AO.34.003267

Applied Optics
Vol. 34,
Issue 18,
pp. 3267-3273
(1995)
•https://doi.org/10.1364/AO.34.003267

Interferometric atmospheric refractive-index environmental monitor

Jacques E. Ludman, Jacques J. Ludman, Heidi Callahan, H. John Caulfield, David Watt, John L. Sampson, John Robinson, Seth Davis, and Arlon Hunt

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Jacques E. Ludman, Jacques J. Ludman, Heidi Callahan, H. John Caulfield, David Watt, John L. Sampson, John Robinson, Seth Davis, and Arlon Hunt, "Interferometric atmospheric refractive-index environmental monitor," Appl. Opt. 34, 3267-3273 (1995)

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Abstract

Long, open-path, outdoor interferometric measurement of the index of refraction as a function of wavelength (spectral refractivity) requires a number of innovations. These include active compensation for vibration and turbulence. The use of electronic compensation produces an electronic signal that is ideal for extracting data. This allows the appropriate interpretation of those data and the systematic and fast scanning of the spectrum by the use of bandwidths that are intermediate between lasers (narrow bandwidth) and white light (broad bandwidth). An Environmental Interferometer that incorporates these features should be extremely valuable in both pollutant detection and pollutant identification. Spectral refractivity measurements complement the information available from spectral absorption instruments (e.g., a Fourier-transform infrared spectrometer). The Environmental Interferometer currently uses an electronic compensating device with a 1-kHz response time, and therefore rapid spectral scans are feasible so that it is possible to monitor the time evolution of pollutant events.

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Pollutant	α _P	∊_min (ppb)
Air	0.00
O₂	0.22	231
O₃	2.23	22
SO₂	3.67	13
CO	0.42	117
H₂O	0.40	123
HCl	1.54	32
N₂O	2.16	23
Chloroform	11.51	4

Abstract

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Applied Optics