Empirical correction of multifilter rotating shadowband radiometer (MFRSR) aerosol optical depths for the aerosol forward scattering and development of a long-term integrated MFRSR-Cimel dataset at Lampedusa

Alcide di Sarra; Damiano Sferlazzo; Daniela Meloni; Fabrizio Anello; Carlo Bommarito; Stefano Corradini; Lorenzo De Silvestri; Tatiana Di Iorio; Francesco Monteleone; Giandomenico Pace; Salvatore Piacentino; Sergio Pugnaghi

doi:10.1364/AO.54.002725

Applied Optics
Vol. 54,
Issue 10,
pp. 2725-2737
(2015)
•https://doi.org/10.1364/AO.54.002725

Empirical correction of multifilter rotating shadowband radiometer (MFRSR) aerosol optical depths for the aerosol forward scattering and development of a long-term integrated MFRSR-Cimel dataset at Lampedusa

Alcide di Sarra, Damiano Sferlazzo, Daniela Meloni, Fabrizio Anello, Carlo Bommarito, Stefano Corradini, Lorenzo De Silvestri, Tatiana Di Iorio, Francesco Monteleone, Giandomenico Pace, Salvatore Piacentino, and Sergio Pugnaghi

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Alcide di Sarra, Damiano Sferlazzo, Daniela Meloni, Fabrizio Anello, Carlo Bommarito, Stefano Corradini, Lorenzo De Silvestri, Tatiana Di Iorio, Francesco Monteleone, Giandomenico Pace, Salvatore Piacentino, and Sergio Pugnaghi, "Empirical correction of multifilter rotating shadowband radiometer (MFRSR) aerosol optical depths for the aerosol forward scattering and development of a long-term integrated MFRSR-Cimel dataset at Lampedusa," Appl. Opt. 54, 2725-2737 (2015)

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- Atmospheric and Oceanic Optics
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About this Article
History
- Original Manuscript: October 7, 2014
- Revised Manuscript: January 12, 2015
- Manuscript Accepted: February 5, 2015
- Published: March 25, 2015

Abstract

Aerosol optical properties have been measured on the island of Lampedusa (35.5°N, 12.6°E) with seven-band multifilter rotating shadowband radiometers (MFRSRs) and a CE 318 Cimel sunphotometer (part of the AERONET network) since 1999. Four different MFRSRs have operated since 1999. The Cimel sunphotometer has been operational for a short period in 2000 and in 2003–2006 and 2010–present. Simultaneous determinations of the aerosol optical depth (AOD) from the two instruments were compared over a period of almost 4 years at several wavelengths between 415 and 870 nm. This is the first long-term comparison at a site strongly influenced by desert dust and marine aerosols and characterized by frequent cases of elevated AOD. The datasets show a good agreement, with MFRSR underestimating the Cimel AOD in cases with low Ångström exponent; the underestimate decreases for increasing wavelength and increases with AOD. This underestimate is attributed to the effect of aerosol forward scattering on the relatively wide field of view of the MFRSR. An empirical correction of the MFRSR data was implemented. After correction, the mean bias (MB) between MFRSR and Cimel simultaneous AOD determinations is always smaller than 0.004, and the root mean square difference is $\leq 0.031$ at all wavelengths. The MB between MFRSR and Cimel monthly averages (for months with at least 20 days with AOD determinations) is 0.0052. Thus, by combining the MFRSR and Cimel observations, an integrated long-term series is obtained, covering the period 1999–present, with almost continuous measurements since early 2002. The long-term data show a small (nonstatistically significant) decreasing trend over the period 2002–2013, in agreement with independent observations in the Mediterranean. The integrated Lampedusa dataset will be used for aerosol climatological studies and for verification of satellite observations and model analyses.

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Instrument	SN	Bands
MFRSR	215	415.5, 499.5, 614.5, 671.5, 868.5, 937.0 nm
MFRSR	424	415.6, 495.7, 614.6, 672.8, 868.7, 939.6 nm
MFRSR	499	416.0, 496.8, 611.7, 671.2, 868.3, 938.3 nm
MFRSR	586	414.7, 495.5, 613.6, 672.1, 869.2, 937.0 nm
Cimel	172, 1	440.6, 675.0, 868.8, 936.1, 1020.6 nm
Cimel	172, 2	338.9, 379.2, 440.6, 500.8, 675.0, 869.3, 936.1, 1020.6 nm
Cimel	172, 3	339.6, 379.2, 440.6, 500.8, 675.0, 869.3, 936.1, 1020.6 nm

Wavelength (nm)	MB	RMSD	Number of Data Pairs
416	$- 0.016$	0.042	8021
440.6	$- 0.018$	0.042	15481
500	$- 0.016$	0.037	16769
614	$- 0.011$	0.032	16769
672	$- 0.009$	0.030	16769
868	$+ 0.002$	0.023	16769

Wavelength (nm)	Class 1 MB	Class 2 MB	Class 1 RMSD	Class 2 RMSD
416	$- 0.0061$	$- 0.034$	0.03	0.057
440.6	$- 0.0073$	$- 0.032$	0.021	0.023
500	$- 0.0052$	$- 0.030$	0.023	0.049
614	$- 0.0031$	$- 0.022$	0.022	0.042
672	$- 0.0022$	$- 0.018$	0.021	0.039
868	$+ 0.006$	$- 0.004$	0.020	0.030

Wavelength (nm)	$a$	$b$	$c$	$r^{2}$
416	0.01314	1.01344	0.1829	0.9808
440.6	$- 0.000967$	1.10966	0.09314	0.9730
500	$- 0.005220$	1.16291	0.02047	0.9810
614	$- 0.011024$	1.16283	0.006833	0.9841
672	$- 0.01573$	1.17089	0.002705	0.9850
675	$- 0.01598$	1.17084	0.002961	0.9851
869	$- 0.02472$	1.15399	–0.005829	0.9892

Wavelength (nm)	MB	RMSD
416	$- 0.0038$	0.030
440.6	$- 0.0041$	0.031
500	$- 0.0029$	0.024
614	$- 0.0018$	0.023
672	$- 0.0014$	0.022
869	$+ 0.0035$	0.018

Parameter	Value
${AOD}_{0}$	0.18771
$a$	$- 0.00152$
$b$	0.0723
$φ_{1}$	$- 1.4821$
${AOD}_{1}$	0.1883
$c$	$- 0.00141$

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Applied Optics