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Laboratoire d’Optique Atmosphérique, Université des Sciences et Technologies de Lille, FRANCE Aerosols spatial distribution (vertical / horizontal) using.

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Presentation on theme: "Laboratoire d’Optique Atmosphérique, Université des Sciences et Technologies de Lille, FRANCE Aerosols spatial distribution (vertical / horizontal) using."— Presentation transcript:

1 Laboratoire d’Optique Atmosphérique, Université des Sciences et Technologies de Lille, FRANCE Aerosols spatial distribution (vertical / horizontal) using the multi-wavelength airborne sun-photometer PLASMA

2 The purpose of the development of airborne multi-wavelength sun photometer was to design an instrument that would directly measure the vertical profiles of AOD at different wavelengths in order to make these data for validation of ground-based and space-borne LIDAR measurements. LIDAR measures the backscattered laser light and the LIDAR equation cannot be solved without an additional constraint such as independent optical depth measurements easy to derive as long as the photometer is well calibrated. Thus, the first objective of PLASMA was to have a tool for the validation of LIDAR data. It was decided to use a wide spectral range to be able to derive information on aerosol size distribution from AOD measurements (King et al., 1978). Thus, the second objective was to get the size distributions of aerosol particles at different altitudes. Since last decades, similar airborne sunphotometers were developed (Matsumoto et al., 1987; Schmid et al., 2003; Asseng et al., 2004) but the PLASMA feature is its lightness so that it can be easily installed on a small airplane or an automobile. That was the third objective: the mobility of the instrument. As the instrument must be installed on the moving platform, the system requires accurate Sun tracking and connection to the GPS navigation system. Moreover, as the airplane speed is about 200 km/h, the frequency of the measurements at different channels must also be high enough for acquiring a whole data set within around one second. The installation on the body of the aircraft or on the roof of the automobile results in the necessity of complex computer control. A sophisticated software is required for the best automatisation of the measurements. Introduction

3 Airborne sun photometer PLASMA Photomètre Léger Aéroporté pour la Surveillance des Masses d’Air 3 15 channels 340 – 2250 nm

4 Sun photometer PLASMA 4 Debuggage session on Highway, Near Lille, 2009

5 Airborne sun photometer PLASMA 5

6 Langley Calibration (like AERONET master) 6 τ

7 Inter-calibration (like AERONET Field instrument) 7 only CIMEL wavelengths can be calibrated

8 PLASMA advantages wide spectral range: 340 – 2250 nm accurate Sun tracking weight: 3.5 kg + 2-4 kg for electronics frequency of measurements: 1 measurement in 100 m for a speed 200 km/h 8

9 Example of Ground-based measurements 9 Beijing PLASMA is the instrument #650 AERONET database 0.05 < ΔAOD < 0.01

10 10 PLASMA data inversion Airborne measurements: Dakar – M’Bour

11 11 PLASMA data inversion Airborne measurements: Dakar – M’Bour Spectral AOD + refractive index from AERONET at all altitudes Size Distribution change with altitude Torres et al., 2013, LOA

12

13

14 Automobile measurements: Tenerife experiment 14 13/01/2011

15 Automobile measurements: DRAGON campaign 15 PLASMA AOD Lidar profile Mortier et al., 2012 20/07/2011

16 Automobile measurements: DRAGON campaign 16 PLASMA vs. AERONET DRAGON 20/07/2011

17 References : Sauvage B., Mise au point d’un photomètre multispectral embarqué sur avion (PLASMA) : participation et analyse de campagnes de mesures, Mémoire de stage de Master 2 de Béatrice Sauvage Parcours recherche ‘Optique, Physique Moléculaire et Atmosphérique’, Laboratoire d’Optique Atmosphérique, Lille 1, Juin 2008 Karol Y., D. Tanre, P. Goloub, C. Vervaerde, J. Y. Balois, L. Blarel, T. Podvin, A. Mortier, A. Chaikovsky, Airborne sunphotometer PLASMA: concept, measurements, comparison of aerosol extinction vertical profile with lidar, Atmos. Meas. Tech. Discuss., 5, 1–22, 2012 http://www.atmos-meas-tech-discuss.net/5/1/2012/ doi:10.5194/amtd-5-1-2012/http://www.atmos-meas-tech-discuss.net/5/1/2012/ doi:10.5194/amtd-5-1-2012/ Karol Y., Determination of optical and microphysical properties of atmospheric aerosols from multi-wavelength airborne sun photometer, Thèse en co-tutelle Lille1-NBAS, 2013. Mortier A., P. Goloub, B. Holben, T. Podvin, L. Blarel, C. Verwaerde, Y. Karol, I. Slutsker, J- Y. Balois, D. Tanre, T. Berkoff, S Victori and R. Mathieu, Aerosol spatial distribution during DRAGON experiment as seen by a mobile ground-based Lidar-Sunphotometer system, International Laser and Radar Conference, Jun 25- 29th 2012, Porto Heli, Greece, P. 411-414 Torres et al, Plasma in Charmex, ChArMEx Results & Perspectives Meeting, Paris (Ballon de Paris, Parc André Citroën) 16-17 Sept. 2013 Torres et al, ADRIMED/Plasma and Lampedusa, Meeting Lampedusa, Créteil (LISA), 24-25 October 2013. Torres et al, First Retrievals Of Aerosol Properties Derived From Measurements Of The New Airborne Sunphotometer PLASMA During The Campaigns SHADOWS And ChArMEx. 7th International Workshop on Sand/Duststorms and Associated Dustfall, ESA/ESRIN, Frascati (Rome), Italy, 2-4 December 2013. Torres et al., first analysis of the aerosol properties derived from Measurements Of The New Airborne Sunphotometer PLASMA During The Campaigns SHADOWS And ChArMEx. Ateliers de Modélisation de l'Atmosphère 2014, Toulouse, France, 20-22 January 2014. 17/51

18 18/51 The team: C. Vervaerde, L. Blarel, T. Podvin, J.-Y. Balois, A. Mortier, B. Torres, P. Goloub, D. Tanré, Y. Karol, R. Loisil, C. Delegove (with contributions from O. Dubovik, T. Lapionak, Y. Derimian)

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