Your search keyword '"Oduber F"' showing total 2 results

1. Scavenging of submicron aerosol particles in a suburban atmosphere: The raindrop size factor.

Author

Blanco-Alegre C, Calvo AI, Castro A, Oduber F, Alonso-Blanco E, and Fraile R

Subjects

Aerosols analysis, Atmosphere, Environmental Monitoring, Particle Size, Rain, Air Pollutants analysis

Abstract

This paper studies the below-cloud scavenging caused by precipitation on ultrafine and accumulation modes, as well as the role of the different raindrop sizes in an urban environment. The equipment used to measure aerosol particles and raindrop variables includes a scanning mobility particle sizer spectrometer-SMPS and a Laser Precipitation Monitor (LPM), respectively. An analysis of the scavenging efficiency and the scavenging coefficient (λ) by modes and rain intensities was carried out. The main results observed have been: i) the nucleation (between 14 and 30 nm), Aitken (between 30 and 100 nm), accumulation 1 (between 100 and 300) and accumulation 2 (between 300 and 1000 nm) modes presented a scavenging efficiency of 15, 4, 22 and 21%, respectively; ii) events with rain intensities between 1 and 3 mm h -1 caused less scavenging in all modes; iii) raindrop sizes between 1.25 and 3.5 mm scavenged mainly particle sizes between 70 and 250 nm. Lower scavenging was observed on particle sizes >300 nm, and particle sizes >600 nm were only scavenged by raindrop sizes >4.75 mm; iv) the respirable fraction before and after the rain events presented a statically significant decrease of -35%. The combination in this study of SMPS and disdrometer measurements has resulted in a more detailed characterization of the influence of this process on the submicrometer aerosol fraction, noting that below-cloud scavenging is one of the main removal pathways for submicrometer aerosol particles. This study thus contributes to improving the current state of knowledge of below-cloud scavenging., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

2. Quantification of source specific black carbon scavenging using an aethalometer and a disdrometer.

Author

Blanco-Alegre C, Calvo AI, Coz E, Castro A, Oduber F, Prévôt ASH, Močnik G, and Fraile R

Subjects

Absorption, Physicochemical, Arctic Regions, Spain, Weather, Aerosols analysis, Air Pollutants analysis, Carbon analysis, Environmental Monitoring methods, Fossil Fuels analysis, Soot analysis, Wood anatomy & histology

Abstract

Aerosol black carbon (BC) is the second strongest contributor to global warming, after CO 2 , and it is linked to many adverse health effects. A sampling campaign of 15 months was carried out in León (Spain) in order to evaluate the scavenging of BC with an ensemble aethalometer-disdrometer. The aethalometer provides the concentration of equivalent black carbon (eBC), and the disdrometer, the raindrop size distribution. A total of seventy-five rain events were studied and in 73% of them there was an effective (eBC initial  > eBC final ) scavenging, with a mean decrease of 48 ± 37% in long rain events (>8 h) and 39 ± 38% in short rain events. The scavenging of BC is strongly related to its source. Thus, the scavenging coefficient (SC) mean value of the BC from fossil fuel (eBC ff ) for short and long rain events was 5.1 10 -5 and 1.3 10 -5 s -1 , respectively. For the BC from biomass burning (eBC bb ), the SC values were 1.6 10 -4 and 2.8 10 -5 s -1 in short and long events, respectively. There was a significant positive correlation between the SC and the number of drops with diameters between 0.375 and 2.5 mm. Rain scavenging of eBC was analyzed depending on the air mass origin obtaining an effective scavenging for air masses from Atlantic, Arctic and Africa. A linear model (R 2  = 0.72) was built to estimate the ΔeBC values with variables from an aethalometer, a disdrometer and a weather station: eBC concentration before rain, swept volume and precipitation accumulated. A Kolmogorov-Smirnov statistical test confirmed the goodness of fit of the model to the measured data., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019