Effect of molecular anisotropy on the intensity and degree of polarization of light scattered from model atmospheres

Om P. Bahethi; Robert S. Fraser

doi:10.1364/AO.19.001333

Applied Optics
Vol. 19,
Issue 8,
pp. 1333-1337
(1980)
•https://doi.org/10.1364/AO.19.001333

Effect of molecular anisotropy on the intensity and degree of polarization of light scattered from model atmospheres

Om P. Bahethi and Robert S. Fraser

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Om P. Bahethi and Robert S. Fraser, "Effect of molecular anisotropy on the intensity and degree of polarization of light scattered from model atmospheres," Appl. Opt. 19, 1333-1337 (1980)

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Abstract

Computations of the properties of sunlight scattered from models of the earth–atmosphere system are presented to show the effect of molecular anisotropy on the intensity, flux, and degree of polarization of the scattered light. The values of these parameters change significantly when the anisotropy factor is neglected in the molecular optical thickness and scattering phase matrix. However, if the Rayleigh scattering optical thickness is kept constant and the molecular anisotropy factor is included only in the Rayleigh phase matrix, the flux does not change, the intensity changes by a small amount, but the changes in the degree of polarization are still significant.

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Model/θ	ϕ = 0°					ϕ = 180°

	0°	20°	40°	60°	80°	0°	20°	40°	60°	80°
A	0.0217	0.0292	0.0422	0.0669	0.1545	0.0217	0.0192	0.0235	0.0426	0.1311
B	0.0230	0.0305	0.0438	0.0691	0.1584	0.0230	0.0205	0.0251	0.0449	0.1353
δ	6.0	4.5	3.8	3.3	2.5	6.0	6.8	6.8	5.4	3.2
C	0.0718	0.1426	0.3752	3.146	0.9677	0.0718	0.0496	0.0501	0.0729	0.1251
D	0.0727	0.1429	0.3735	3.116	0.9591	0.0727	0.0509	0.0517	0.0749	0.1269
Δ	1.3	0.2	−0.4	−1.0	−0.9	1.3	2.6	3.2	2.7	1.4

Model/θ	ϕ = 0°					ϕ = 180°

	0°	20°	40°	60°	80°	0°	20°	40°	60°	80°
A	0.0322	0.0404	0.0558	0.0871	0.2042	0.0322	0.0303	0.0371	0.0627	0.1807
B	0.0340	0.0422	0.0579	0.0901	0.2100	0.0340	0.0322	0.0393	0.0659	0.1869
δ	5.6	4.5	3.8	3.4	2.8	5.6	6.3	5.9	5.1	3.4
C	0.0876	0.1598	0.3977	3.184	1.056	0.0876	0.0668	0.0727	0.1106	0.2133
D	0.0890	0.1606	0.3965	3.154	1.048	0.0890	0.0685	0.0747	0.1126	0.2156
Δ	1.6	0.5	−0.3	−1.0	−0.8	1.6	2.5	2.8	1.8	1.1

Model/θ	ϕ = 0°					ϕ = 180°

	0°	20°	40°	60°	80°	0°	20°	40°	60°	80°
A′	0.0300	0.0377	0.0488	0.0684	0.1405	0.0300	0.0252	0.0256	0.0382	0.1117
B′	0.0298	0.0372	0.0480	0.0675	0.1395	0.0298	0.0254	0.0260	0.0388	0.1122
δ′	−0.7	−1.3	−1.6	−1.3	−0.7	−0.7	0.8	1.6	1.6	0.4
C′	0.1489	0.3534	2.670	0.6033	0.5093	0.1489	0.0832	0.0652	0.0764	0.1195
D′	0.1488	0.3530	2.669	0.6025	0.5088	0.1488	0.0833	0.0652	0.0769	0.1197
Δ′	−0.1	−0.1	0.0	−0.1	−0.1	−0.1	0.1	0.0	0.7	0.2

Model/θ	ϕ = 0°					ϕ = 180°

	0°	20°	40°	60°	80°	0°	20°	40°	60°	80°
A	0.0217	0.0292	0.0422	0.0669	0.1545	0.0217	0.0192	0.0235	0.0426	0.1311
B	0.0230	0.0305	0.0438	0.0691	0.1584	0.0230	0.0205	0.0251	0.0449	0.1353
δ	6.0	4.5	3.8	3.3	2.5	6.0	6.8	6.8	5.4	3.2
C	0.0718	0.1426	0.3752	3.146	0.9677	0.0718	0.0496	0.0501	0.0729	0.1251
D	0.0727	0.1429	0.3735	3.116	0.9591	0.0727	0.0509	0.0517	0.0749	0.1269
Δ	1.3	0.2	−0.4	−1.0	−0.9	1.3	2.6	3.2	2.7	1.4

Model/θ	ϕ = 0°					ϕ = 180°

	0°	20°	40°	60°	80°	0°	20°	40°	60°	80°
A	0.0322	0.0404	0.0558	0.0871	0.2042	0.0322	0.0303	0.0371	0.0627	0.1807
B	0.0340	0.0422	0.0579	0.0901	0.2100	0.0340	0.0322	0.0393	0.0659	0.1869
δ	5.6	4.5	3.8	3.4	2.8	5.6	6.3	5.9	5.1	3.4
C	0.0876	0.1598	0.3977	3.184	1.056	0.0876	0.0668	0.0727	0.1106	0.2133
D	0.0890	0.1606	0.3965	3.154	1.048	0.0890	0.0685	0.0747	0.1126	0.2156
Δ	1.6	0.5	−0.3	−1.0	−0.8	1.6	2.5	2.8	1.8	1.1

Abstract

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Applied Optics