Experimental Evidence of the Feeding of the Free Troposphere with Aerosol Particles from the Mixing Layer

Freney, Evelyn; Sellegri, Karine; Asmi, Eija; Singer, Clemence, Rose,; Chauvigné, Aurélien; Jean-Luc, Baray; Colomb, A.; Hervo, Maxime; Montoux, Nadège; Laeticia, Bouvier; Picard, D.

doi:10.4209/aaqr.2015.03.0164

Cited by 18 publications

(22 citation statements)

References 63 publications

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“…For instance, the long-term variation of the particle size distribution has been studied by Venzac et al (2009) [14], and the occurrence of the new particle formation (NPF) process was specifically investigated in several dedicated studies [24,[26][27][28]. Filter measurements, as well as online mass spectrometry analysis, have been used to document the particles chemical composition [19,29,30] and aerosol-cloud interactions were also investigated from this station which offers favorable conditions for such analysis [28,31,32]. The second site, Cézeaux, hereafter referred to as CZ, is located on the University campus in Clermont-Ferrand (420 m a.s.l.…”

Section: Site and Instrumentationsmentioning

confidence: 99%

“…As evidenced in earlier studies [16][17][18] new particle formation (NPF) may have specific characteristics at high altitudes. Once in the FT, aerosol particles have a longer residence time due to the lower frequency at which they are scavenged by clouds and precipitation, allowing them to be transported in the atmosphere for several days [19] increasing their impact on the climate. Additionally, aerosol particles transported into the FT or formed in the FT can be re-injected again into BL, affecting the air quality far from the source region [20,21].…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, these measurements are needed to validate and improve numerical mesoscale or global scale transport models [22]. A number of studies focused on FT conditions from ground-based high altitude sites [3,14,19] or from airborne measurement campaigns [23,24], providing information on aerosol physical and chemical properties in this part of the atmosphere. Fröhlich et al (2015) [25] and Freney et al (2016) [19] showed that the FT air masses are strongly influenced by injections from BL, however, the number of studies comparing the transport from the BL to the FT over long periods of time are rare.…”

Section: Introductionmentioning

confidence: 99%

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Seasonal Variation of Aerosol Size Distribution Data at the Puy de Dôme Station with Emphasis on the Boundary Layer/Free Troposphere Segregation

et al. 2018

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Aerosol particles are important due to their direct and indirect impacts on climate. Within the planetary boundary layer (BL), these particles have a relatively short lifetime due to their frequent removal process by wet deposition. When aerosols are transported into the free troposphere (FT), their atmospheric lifetime increases significantly, making them representative of large spatial areas. In this work, we use a combination of in situ measurements performed at the high altitude PUY (Puy de Dôme, 45 • 46 N, 2 • 57 E, 1465 m a.s.l) station, together with LIDAR profiles at Clermont-Ferrand for characterizing FT conditions, and further characterize the physical properties of aerosol in this poorly documented area of the atmosphere. First, a combination of four criteria was used to identify whether the PUY station lies within the FT or within the BL. Results show that the PUY station is located in BL with frequencies ranging from 50% during the winter, up to 97% during the summer. Then, the classification is applied to a year-long dataset (2015) of particle size distribution data to study the differences in particle physical characteristics (size distribution) and black carbon (BC) concentrations between the FT and the BL. Although BC, Aitken, and the accumulation mode particles concentrations were higher in the BL than in the FT in winter and autumn, they were measured to be higher in the FT compared to BL in spring. No significant difference between the BL and the FT concentrations was observed for the nucleation mode particles for all seasons, suggesting a continuous additional source of nucleation mode particles in the FT during winter and autumn. Coarse mode particle concentrations were found higher in the FT than in the BL for all seasons and especially during summer. This indicates an efficient long-range transport of large particles in the FT from distant sources (marine and desert) due to higher wind speeds in the FT compared to BL. For FT air masses, we used 204-h air mass back-trajectories combined with boundary layer height estimations from ECMWF ERA-Interim to assess the time they spent in the FT since their last contact with the BL and to evaluate the impact of this parameter on the aerosol properties. We observed that even after 75 h without any contact with the BL, FT aerosols preserve specific properties of their air mass type.

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Section: Site and Instrumentationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Seasonal Variation of Aerosol Size Distribution Data at the Puy de Dôme Station with Emphasis on the Boundary Layer/Free Troposphere Segregation

et al. 2018

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“…Each cluster of trajectories is calculated every 15 min for 48 h of back-trajectories, for each day of precipitation sampling with a starting vertical level defined using ERA-Interim humidity and cloud parameters, and varying from 1 to 5 km. LACYTRAJ has previously been used to study long-range inter-hemispheric transport of carbon monoxide [38], interactions between the mixing layer and the free troposphere [39] or jet stream dynamics [40]. Based on previous studies of the atmosphere at this site [41], we distinguished categories in the geographical origin of air masses; here 3 sectors were defined: West (air masses from the Atlantic Ocean), North-East (Continental source) and South (Mediterranean Sea).…”

Section: Meteorological Data and Backward Trajectory Plotsmentioning

confidence: 99%

Atmospheric Processing and Variability of Biological Ice Nucleating Particles in Precipitation at Opme, France

et al. 2017

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Atmospheric ice nucleating particles (INPs) contribute to initiate precipitation. In particular, biological INPs act at warmer temperatures than other types of particles (>−10 • C) therefore potentially defining precipitation distribution. Here, in order to identify potential environmental drivers in the distribution and fate of biological INPs in the atmosphere, we conducted a mid-term study of the freezing characteristics of precipitation. A total of 121 samples were collected during a period of >1.5 years at the rural site of Opme (680 m a.s.l. (above sea level), France). INP concentration ranged over two orders of magnitude at a given temperature depending on the sample; there were <1 INPs mL −1 at ≥−5 • C,~0.1 to 10 mL −1 between −5 • C and −8 • C, and~1 to 100 mL −1 at colder temperatures. The data support the existence of an intimate natural link between biological INPs and hydrological cycles. In addition, acidification was strongly correlated with a decrease of the freezing characteristics of the samples, suggesting that human activities impact the role of INPs as triggers of precipitation. Water isotope ratio measurements and statistical comparison with aerosol and cloud water data confirmed some extent of INP partitioning in the atmosphere, with the INPs active at the warmest temperatures tending to be more efficiently precipitated.

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“…Evidence of anthropogenic emissions transported from the planetary mixing layer to the free troposphere was presented by Freney et al (2016) using in-situ measurements of aerosol chemical and physical properties during a cold period in February 2012 at the Puy de Dôme station, as well as LIDAR measurements (at the Cezeaux site) in France. A change in aerosol physical and chemical properties was observed in the free troposphere with an increase in aerosol mass concentrations, number of larger particles, and presence of organic and nitrate particles.…”

Section: Classification Of and The Exchange Between The Free Troposphmentioning

confidence: 99%

Overview of the Special Issue “Selected Papers from the 2nd Atmospheric Chemistry and Physics at Mountain Sites Symposium”

Hallar

Andrews

Bukowiecki

et al. 2016

Aerosol Air Qual. Res.

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Mountain sites provide a unique window on atmospheric chemistry and physics. These sites allow for continuous observations at high elevation, often in the free troposphere, where many important processes occur. Observations at these mountain sites allow for studies on long-range transport of pollution, cloud and precipitation processes, boundary layer ventilation and long-term observations of climate relevant gases and aerosols. However operating at mountain sites presents a unique set of challenges, and for this reason scientists doing research at these sites sought a forum to share knowledge on both the science and challenges of working at these sites.

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Experimental Evidence of the Feeding of the Free Troposphere with Aerosol Particles from the Mixing Layer

Cited by 18 publications

References 63 publications

Seasonal Variation of Aerosol Size Distribution Data at the Puy de Dôme Station with Emphasis on the Boundary Layer/Free Troposphere Segregation

Seasonal Variation of Aerosol Size Distribution Data at the Puy de Dôme Station with Emphasis on the Boundary Layer/Free Troposphere Segregation

Atmospheric Processing and Variability of Biological Ice Nucleating Particles in Precipitation at Opme, France

Overview of the Special Issue “Selected Papers from the 2nd Atmospheric Chemistry and Physics at Mountain Sites Symposium”

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