Airborne lidar measurements of aerosol spatial distribution and optical properties over the Atlantic Ocean during a European pollution outbreak of ACE-2

Flamant, Cyrille; Pelon, Jacques; Chazette, Patrick; Trouillet, Vincent; Quinn, Patricia K.; Frouin, Robert; Bruneau, Didier; Leon, Jean Francois; Bates, T. S.; Johnson, James R.; Livingston, John H.

doi:10.1034/j.1600-0889.2000.00083.x

Cited by 42 publications

(28 citation statements)

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“…Between 18 and 26 June (Fig. 4), the BER reaches ∼ 0.04 sr −1 (LR = 25 sr) as observed by Flamant et al (2000) for marine aerosols over the open ocean. Nevertheless, we also note weak-medium surface wind speeds between 2 and 8 m s −1 , which are not favourable to a strong contribution of sea salt particles in the lower troposphere.…”

Section: Discussionmentioning

confidence: 69%

Temporal consistency of lidar observations during aerosol transport events in the framework of the ChArMEx/ADRIMED campaign at Minorca in June 2013

et al. 2016

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Abstract. We performed synergetic daytime and nighttime active and passive remote-sensing observations at Minorca (Balearic Islands, Spain), over more than 3 weeks during the Chemistry-Aerosol Mediterranean Experiment/Aerosol Direct Radiative Effect in the Mediterranean (ChArMEx/ADRIMED) special observation period (SOP 1a, June-July 2013). We characterized the aerosol optical properties and type in the low and middle troposphere using an automated procedure combining Rayleigh-Mie-Raman lidar (355, 387 and 407 nm) with depolarization (355 nm) and AERONET Cimel ® sun-photometer data. Results show a high variability due to varying dynamical forcing. The mean column-averaged lidar backscatter-to-extinction ratio (BER) was close to 0.024 sr −1 (lidar ratio of ∼ 41.7 sr), with a large dispersion of ±33 % over the whole observation period due to changing atmospheric transport regimes and aerosol sources. The ground-based remote-sensing measurements, coupled with satellite observations, allowed the documentation of (i) dust particles up to 5 km (above sea level) in altitude originating from Morocco and Algeria from 15 to 18 June with a peak in aerosol optical thickness (AOT) of 0.25 ± 0.05 at 355 nm, (ii) a long-range transport of biomass burning aerosol (AOT = 0.18 ± 0.16) related to North American forest fires detected from 26 to 28 June 2013 by the lidar between 2 and 7 km and (iii) mixture of local sources including marine aerosol particles and pollution from Spain. During the biomass burning event, the high value of the particle depolarization ratio (8-14 %) may imply the presence of dust-like particles mixed with the biomass burning aerosols in the mid-troposphere. For the field campaign period, we also show linearity with SEVIRI retrievals of the aerosol optical thickness despite 35 % relative bias, which is discussed as a function of aerosol type.

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Section: Discussionmentioning

confidence: 69%

Temporal consistency of lidar observations during aerosol transport events in the framework of the ChArMEx/ADRIMED campaign at Minorca in June 2013

et al. 2016

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“…[3] Vertical aerosol profiles can be obtained using ground based lidars [Whiteman et al, 1992;Ansmann et al, 2000], airborne lidars [Flamant et al, 2000;Wagner et al, 2009] or space-borne lidars [Winker et al, 2010]. Besides, measurements with balloons [Maletto et al, 2003] or with airborne in situ instruments [Brenninkmeijer et al, 1999;Haywood et al, 2003] can be applied.…”

Section: Introductionmentioning

confidence: 99%

Two years of free‐tropospheric aerosol layers observed over Portugal by lidar

et al. 2013

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[1] Multi-wavelength Raman light detection and ranging (lidar) observations were analyzed, which were performed in Évora, Portugal, during more than 2 years on a regular basis in the framework of the European Aerosol Research Lidar Network (EARLINET). An aerosol characterization in terms of the lidar ratios at 355 and 532 nm and the extinction and backscatter related Ångström exponents is presented. Aerosol layers in the free troposphere were classified according to their origin. Clear differences in the intensive optical properties were found for layers of mineral dust from the Sahara and from Asia, of anthropogenic aerosol from Europe and from North America, as well as of biomass burning smoke from the Iberian Peninsula and from North America, respectively. In general, the mean Ångström exponents of aerosol layers of the same type, but from closer source regions, were smaller than those from aerosol layers transported over a longer distance. This hints at the deposition of large particles along the transportation path, especially for anthropogenic aerosol and mineral dust. Besides, the seasonal behavior of aerosol in the free troposphere over Évora was studied. Seventy-three percent of the detected layers were observed during spring and summer. On average, the layers were highest in summer with an overall mean layer height of (3.8˙1.9) km above sea level (asl), and lowest in winter with (2.3˙0.9) km asl.

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“…A complete set of experiments to determine the aerosol spatial distribution and optical properties was conducted in the framework of Aerosol Characterization Experiment (ACE). ACE‐2 over the Atlantic Ocean, for example, measured the particle size distribution, aerosol optical depth (AOD) (using a Sun photometer), aerosol extinction coefficient (using a lidar), and scattering coefficient (using a nephelometer) [ Flamant et al , 2000].…”

Section: Introductionmentioning

confidence: 99%

Aerosol optical characterization by nephelometer and lidar: The Baltimore Supersite experiment during the Canadian forest fire smoke intrusion

Adam

Pahlow

Kovalev³

et al. 2004

J. Geophys. Res.

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[1] High spatial and temporal resolution elastic backscatter lidar data from Baltimore are analyzed with a near-end approach to estimate vertical profiles of the aerosol extinction coefficient. The near-end approach makes use of the (1) aerosol scattering coefficient measured at the surface with a nephelometer (0.530 mm), (2) surface level particle size distribution, and (3) refractive index calculated using Mie theory to estimate the aerosol extinction coefficient boundary condition for the lidar equation. There was a broad range of atmospheric turbidity due to a strong haze event, which occurred because of smoke transport from Canadian forest fires, and led to a wide range of observed atmospheric properties. The index of refraction for aerosols estimated during the entire study period is 1.5-0.47 i, which is typical for soot. The measured surface level aerosol scattering coefficient ranged from s p = 0.002 to s p = 0.541 km À1 , and the computed aerosol extinction coefficient spanned values k p = 0.01 to k p = 1.05 km À1 . The derived mass concentration and the mass scattering ranges were 3.96-194 mg m À3 and 0.05-3.260 m 2 g À1 , respectively. The aerosol optical properties were dominated by light absorption by soot.

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Airborne lidar measurements of aerosol spatial distribution and optical properties over the Atlantic Ocean during a European pollution outbreak of ACE-2

Cited by 42 publications

References 1 publication

Temporal consistency of lidar observations during aerosol transport events in the framework of the ChArMEx/ADRIMED campaign at Minorca in June 2013

Temporal consistency of lidar observations during aerosol transport events in the framework of the ChArMEx/ADRIMED campaign at Minorca in June 2013

Two years of free‐tropospheric aerosol layers observed over Portugal by lidar

Aerosol optical characterization by nephelometer and lidar: The Baltimore Supersite experiment during the Canadian forest fire smoke intrusion

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