Aerosol absorption measurement by a Shack–Hartmann wavefront sensor

Jay E. Land

doi:10.1364/AO.492066

Applied Optics
Vol. 62,
Issue 18,
pp. 4836-4847
(2023)
•https://doi.org/10.1364/AO.492066

Aerosol absorption measurement by a Shack–Hartmann wavefront sensor

Jay E. Land

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Jay E. Land, "Aerosol absorption measurement by a Shack–Hartmann wavefront sensor," Appl. Opt. 62, 4836-4847 (2023)

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Abstract

Researchers at the U.S. Army Space and Missile Defense Command have developed a method for quantifying high energy near-infrared (NIR) laser heating of air resulting from laser absorption of suspended dry aerosols in a controlled environmental chamber. The measurements were accomplished using an ISO standard test dust and NIR high energy laser using a Shack–Hartmann wavefront sensor. This paper presents the methodology of the measurement as well as the quantitative reconstruction of the air temperature profile, absorption efficiency, and imaginary refractive index of the aerosol. The resulting measurement of the aerosol imaginary index of refraction was significantly lower than values typically found in the literature from measurements using low power techniques. These findings are in general agreement with other recently published works that have found that previously published values of mineral dust aerosols could be significantly overestimated.

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Data availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the author upon reasonable request.

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Dust Type	$P_{L}$ $(k W)$	$Γ_{532}$ (%)	$Γ_{532_{M i e}}$ (%)	$N_{pk}$ $(P / {c m}^{3})$	$Δ T$ (C)	${\tilde{Q}}_{a b s}$ (%)	$n_{i}$ $(\times 10^{- 5})$	$σ_{n_{i}}$ $(\times 10^{- 6})$
ISO1	19.7	91.5	91.7	504	3.97	0.617	−9.557	5.84
ISO1	10.0	95.0	95.7	324	0.68	0.437	−7.905	5.20
ISO1	15.0	95.0	95.8	312	1.01	0.620	−11.294	7.12
ISO2	10.1	92.3	87.7	513	2.53	0.859	−12.259	6.97
ISO2	15.0	92.3	88.9	477	3.86	0.798	−11.462	6.45
ISO2	10.1	95.9	94.0	302	0.97	0.606	−9.034	5.42
ISO2	15.0	96.4	94.2	300	1.53	0.482	−7.610	4.73
ATD	10.0	93.8	89.6	451	2.62	0.570	−9.150	5.84
ATD	14.9	93.9	90.0	420	3.63	0.560	−9.310	6.00
ATD	10.1	95.4	90.8	287	1.04	0.629	−10.854	6.91
ATD	15.1	95.4	91.2	285	1.43	0.604	−10.594	6.75
ATD	10.0	88.7	94.8	493	2.22	0.664	−11.861	7.42
ATD	13.5	89.7	95.6	470	3.26	0.657	−11.824	7.58

Component	Mass Quantity (%)
Silica (fine dust)	68%–76%
Aluminum oxide	10%–15%
Calcium oxide (mineral)	2%–5%
Potassium oxide (mineral)	2%–5%
Sodium oxide (mineral)	2%–4%
Iron(lll) oxide (hematite)	2%–5%
Magnesium oxide	1%–2%
Titanium dioxide	0.5%–1.0%

Source	$1 σ$ Uncertainty (%)	Contribution to $α_{e f f}$ (%)
$P_{L}$	3.3	3.3
Constants	3.3	3.3
$t_{L}$	0.7	0.7
$Γ_{532}$	3.3	1.7
$α_{e x t}$	3.3	0.03
$δ ϕ_{S H W F S}$	2.3	2.3
Total (RSS)		5.5

Dust Type	$P_{L}$ $(k W)$	$Γ_{532}$ (%)	$Γ_{532_{M i e}}$ (%)	$N_{pk}$ $(P / {c m}^{3})$	$Δ T$ (C)	${\tilde{Q}}_{a b s}$ (%)	$n_{i}$ $(\times 10^{- 5})$	$σ_{n_{i}}$ $(\times 10^{- 6})$
ISO1	19.7	91.5	91.7	504	3.97	0.617	−9.557	5.84
ISO1	10.0	95.0	95.7	324	0.68	0.437	−7.905	5.20
ISO1	15.0	95.0	95.8	312	1.01	0.620	−11.294	7.12
ISO2	10.1	92.3	87.7	513	2.53	0.859	−12.259	6.97
ISO2	15.0	92.3	88.9	477	3.86	0.798	−11.462	6.45
ISO2	10.1	95.9	94.0	302	0.97	0.606	−9.034	5.42
ISO2	15.0	96.4	94.2	300	1.53	0.482	−7.610	4.73
ATD	10.0	93.8	89.6	451	2.62	0.570	−9.150	5.84
ATD	14.9	93.9	90.0	420	3.63	0.560	−9.310	6.00
ATD	10.1	95.4	90.8	287	1.04	0.629	−10.854	6.91
ATD	15.1	95.4	91.2	285	1.43	0.604	−10.594	6.75
ATD	10.0	88.7	94.8	493	2.22	0.664	−11.861	7.42
ATD	13.5	89.7	95.6	470	3.26	0.657	−11.824	7.58

Component	Mass Quantity (%)
Silica (fine dust)	68%–76%
Aluminum oxide	10%–15%
Calcium oxide (mineral)	2%–5%
Potassium oxide (mineral)	2%–5%
Sodium oxide (mineral)	2%–4%
Iron(lll) oxide (hematite)	2%–5%
Magnesium oxide	1%–2%
Titanium dioxide	0.5%–1.0%

Abstract

Data availability

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Equations (26)

Applied Optics