Relation between absorption coefficient and imaginary index of atmospheric aerosol constituents

S. G. Jennings; R. G. Pinnick; J. B. Gillespie

doi:10.1364/AO.18.001368

Relation between absorption coefficient and imaginary index of atmospheric aerosol constituents

S. G. Jennings, R. G. Pinnick, J. B. Gillespie

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Abstract

The absorption coefficient per unit mass α(cm₂ g⁻¹) for aerosols in the wavelength range λ = 1.06–10.6 μm is shown to be a sensitive function of particle size distribution and of both imaginary and real indexes of refraction.Hence the imaginary index of refraction cannot be accurately determined from absorption measurements on an aerosol sample as attempted by S.A.Schleusener et al., Appl.Opt.15, 2546 (1976), unless the size distribution and real index of the aerosol material are known.Similar difficulties arise in attempts to infer imaginary index from transmission measurements through aerosol samples as done by F.E.Volz, Appl.Opt.11, 755 (1972); Appl.Opt.12, 564 (1973) and K.Fischer, Beitr.Phys.Atmos.43, 244 (1970).In addition, scattering losses can further complicate the determination of imaginary index from transmission measurements.

Original language	English
Pages (from-to)	1368-1371
Number of pages	4
Journal	Applied Optics
Volume	18
Issue number	9
DOIs	https://doi.org/10.1364/AO.18.001368
Publication status	Published - May 1979
Externally published	Yes

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title = "Relation between absorption coefficient and imaginary index of atmospheric aerosol constituents",

abstract = "The absorption coefficient per unit mass α(cm2 g−1) for aerosols in the wavelength range λ = 1.06–10.6 μm is shown to be a sensitive function of particle size distribution and of both imaginary and real indexes of refraction.Hence the imaginary index of refraction cannot be accurately determined from absorption measurements on an aerosol sample as attempted by S.A.Schleusener et al., Appl.Opt.15, 2546 (1976), unless the size distribution and real index of the aerosol material are known.Similar difficulties arise in attempts to infer imaginary index from transmission measurements through aerosol samples as done by F.E.Volz, Appl.Opt.11, 755 (1972); Appl.Opt.12, 564 (1973) and K.Fischer, Beitr.Phys.Atmos.43, 244 (1970).In addition, scattering losses can further complicate the determination of imaginary index from transmission measurements.",

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N2 - The absorption coefficient per unit mass α(cm2 g−1) for aerosols in the wavelength range λ = 1.06–10.6 μm is shown to be a sensitive function of particle size distribution and of both imaginary and real indexes of refraction.Hence the imaginary index of refraction cannot be accurately determined from absorption measurements on an aerosol sample as attempted by S.A.Schleusener et al., Appl.Opt.15, 2546 (1976), unless the size distribution and real index of the aerosol material are known.Similar difficulties arise in attempts to infer imaginary index from transmission measurements through aerosol samples as done by F.E.Volz, Appl.Opt.11, 755 (1972); Appl.Opt.12, 564 (1973) and K.Fischer, Beitr.Phys.Atmos.43, 244 (1970).In addition, scattering losses can further complicate the determination of imaginary index from transmission measurements.

AB - The absorption coefficient per unit mass α(cm2 g−1) for aerosols in the wavelength range λ = 1.06–10.6 μm is shown to be a sensitive function of particle size distribution and of both imaginary and real indexes of refraction.Hence the imaginary index of refraction cannot be accurately determined from absorption measurements on an aerosol sample as attempted by S.A.Schleusener et al., Appl.Opt.15, 2546 (1976), unless the size distribution and real index of the aerosol material are known.Similar difficulties arise in attempts to infer imaginary index from transmission measurements through aerosol samples as done by F.E.Volz, Appl.Opt.11, 755 (1972); Appl.Opt.12, 564 (1973) and K.Fischer, Beitr.Phys.Atmos.43, 244 (1970).In addition, scattering losses can further complicate the determination of imaginary index from transmission measurements.

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Relation between absorption coefficient and imaginary index of atmospheric aerosol constituents

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