Your search keyword '"Wex, Heike"' showing total 7 results

1. Understanding aerosol microphysical properties from 10 years of data collected at Cabo Verde based on an unsupervised machine learning classification.

Author

Gong, Xianda, Wex, Heike, Müller, Thomas, Henning, Silvia, Voigtländer, Jens, Wiedensohler, Alfred, and Stratmann, Frank

Subjects

SUPERSATURATION, AEROSOLS, CLOUD condensation nuclei, MACHINE learning, ATMOSPHERIC aerosols, AIR masses

Abstract

The Cape Verde Atmospheric Observatory (CVAO), which is influenced by both marine and desert dust air masses, has been used for long-term measurements of different properties of the atmospheric aerosol from 2008 to 2017. These properties include particle number size distributions (PNSD), light-absorbing carbon (LAC) and concentrations of cloud condensation nuclei (CCN) together with their hygroscopicity. Here we summarize the results obtained for these properties and use an unsupervised machine learning algorithm for the classification of aerosol types. Five types of aerosols, i.e., marine, freshly formed, mixture, moderate dust and heavy dust, were classified. Air masses during marine periods are from the Atlantic Ocean and during dust periods are from the Sahara Desert. Heavy dust was more frequently present during wintertime, whereas the clean marine periods were more frequently present during springtime. It was observed that during the dust periods CCN number concentrations at a supersaturation of 0.30 % were roughly 2.5 times higher than during marine periods, but the hygroscopicity (κ) of particles in the size range from ∼ 30 to ∼ 175 nm during marine and dust periods were comparable. The long-term data presented here, together with the aerosol classification, can be used as a basis to improve our understanding of annual cycles of the atmospheric aerosol in the eastern tropical Atlantic Ocean and on aerosol-cloud interactions and it can be used as a basis for driving, evaluating and constraining atmospheric model simulations. [ABSTRACT FROM AUTHOR]

Published

2022

2. Marine organic matter in the remote environment of the Cape Verde islands – an introduction and overview to the MarParCloud campaign.

Author

van Pinxteren, Manuela, Fomba, Khanneh Wadinga, Triesch, Nadja, Stolle, Christian, Wurl, Oliver, Bahlmann, Enno, Gong, Xianda, Voigtländer, Jens, Wex, Heike, Robinson, Tiera-Brandy, Barthel, Stefan, Zeppenfeld, Sebastian, Hoffmann, Erik Hans, Roveretto, Marie, Li, Chunlin, Grosselin, Benoit, Daële, Veronique, Senf, Fabian, van Pinxteren, Dominik, and Manzi, Malena

Subjects

MICROBIOLOGICAL aerosols, AIR masses, CLOUD condensation nuclei, ORGANIC compounds, SEA surface microlayer, ATMOSPHERIC sciences, ATMOSPHERIC aerosols

Abstract

The project MarParCloud (Marine biological production, organic aerosol Particles and marine Clouds: a process chain) aims to improve our understanding of the genesis, modification and impact of marine organic matter (OM) from its biological production, to its export to marine aerosol particles and, finally, to its ability to act as ice-nucleating particles (INPs) and cloud condensation nuclei (CCN). A field campaign at the Cape Verde Atmospheric Observatory (CVAO) in the tropics in September–October 2017 formed the core of this project that was jointly performed with the project MARSU (MARine atmospheric Science Unravelled). A suite of chemical, physical, biological and meteorological techniques was applied, and comprehensive measurements of bulk water, the sea surface microlayer (SML), cloud water and ambient aerosol particles collected at a ground-based and a mountain station took place. Key variables comprised the chemical characterization of the atmospherically relevant OM components in the ocean and the atmosphere as well as measurements of INPs and CCN. Moreover, bacterial cell counts, mercury species and trace gases were analyzed. To interpret the results, the measurements were accompanied by various auxiliary parameters such as air mass back-trajectory analysis, vertical atmospheric profile analysis, cloud observations and pigment measurements in seawater. Additional modeling studies supported the experimental analysis. During the campaign, the CVAO exhibited marine air masses with low and partly moderate dust influences. The marine boundary layer was well mixed as indicated by an almost uniform particle number size distribution within the boundary layer. Lipid biomarkers were present in the aerosol particles in typical concentrations of marine background conditions. Accumulation- and coarse-mode particles served as CCN and were efficiently transferred to the cloud water. The ascent of ocean-derived compounds, such as sea salt and sugar-like compounds, to the cloud level, as derived from chemical analysis and atmospheric transfer modeling results, denotes an influence of marine emissions on cloud formation. Organic nitrogen compounds (free amino acids) were enriched by several orders of magnitude in submicron aerosol particles and in cloud water compared to seawater. However, INP measurements also indicated a significant contribution of other non-marine sources to the local INP concentration, as (biologically active) INPs were mainly present in supermicron aerosol particles that are not suggested to undergo strong enrichment during ocean–atmosphere transfer. In addition, the number of CCN at the supersaturation of 0.30 % was about 2.5 times higher during dust periods compared to marine periods. Lipids, sugar-like compounds, UV-absorbing (UV: ultraviolet) humic-like substances and low-molecular-weight neutral components were important organic compounds in the seawater, and highly surface-active lipids were enriched within the SML. The selective enrichment of specific organic compounds in the SML needs to be studied in further detail and implemented in an OM source function for emission modeling to better understand transfer patterns, the mechanisms of marine OM transformation in the atmosphere and the role of additional sources. In summary, when looking at particulate mass, we see oceanic compounds transferred to the atmospheric aerosol and to the cloud level, while from a perspective of particle number concentrations, sea spray aerosol (i.e., primary marine aerosol) contributions to both CCN and INPs are rather limited. [ABSTRACT FROM AUTHOR]

Published

2020

3. CCN measurements at the Princess Elisabeth Antarctica research station during three austral summers.

Author

Herenz, Paul, Wex, Heike, Mangold, Alexander, Laffineur, Quentin, Gorodetskaya, Irina V., Fleming, Zoë L., Panagi, Marios, and Stratmann, Frank

Subjects

ATMOSPHERIC aerosols, CLOUD condensation nuclei, PARTICLE size distribution, AITKEN particles, CLOUD droplets, AIR masses, ANTARCTIC research stations

Abstract

For three austral summer seasons (2013–2016, each from December to February) aerosol particles arriving at the Belgian Antarctic research station Princess Elisabeth (PE) in Dronning Maud Land in East Antarctica were characterized. This included number concentrations of total aerosol particles (NCN) and cloud condensation nuclei (NCCN), the particle number size distribution (PNSD), the aerosol particle hygroscopicity, and the influence of the air mass origin on NCN and NCCN. In general NCN was found to range from 40 to 6700 cm -3 , with a median of 333 cm -3 , while NCCN was found to cover a range between less than 10 and 1300 cm -3 for supersaturations (SSs) between 0.1 % and 0.7 %. It is shown that the aerosol is dominated by the Aitken mode, being characterized by a significant amount of small, and therefore likely secondarily formed, aerosol particles, with 94 % and 36 % of the aerosol particles smaller than 90 and ≈35 nm, respectively. Measurements of the basic meteorological parameters as well as the history of the air masses arriving at the measurement station indicate that the station is influenced by both marine air masses originating from the Southern Ocean and coastal areas around Antarctica (marine events – MEs) and continental air masses (continental events – CEs). CEs, which were defined as instances when the air masses spent at least 90 % of the time over the Antarctic continent during the last 10 days prior to arrival at the measurements station, occurred during 61 % of the time during which measurements were done. CEs came along with rather constant NCN and NCCN values, which we denote as Antarctic continental background concentrations. MEs, however, cause large fluctuations in NCN and NCCN , with low concentrations likely caused by scavenging due to precipitation and high concentrations likely originating from new particle formation (NPF) based on marine precursors. The application of HYSPLIT back trajectories in form of the potential source contribution function (PSCF) analysis indicate that the region of the Southern Ocean is a potential source of Aitken mode particles. On the basis of PNSDs, together with NCCN measured at an SS of 0.1 %, median values for the critical diameter for cloud droplet activation and the aerosol particle hygroscopicity parameter κ were determined to be 110 nm and 1, respectively. For particles larger than ≈110 nm the Southern Ocean together with parts of the Antarctic ice shelf regions were found to be potential source regions. While the former may contribute sea spray particles directly, the contribution of the latter may be due to the emission of sea salt aerosol particles, released from snow particles from surface snow layers, e.g., during periods of high wind speed, leading to drifting or blowing snow. The region of the Antarctic inland plateau, however, was not found to feature a significant source region for aerosol particles in general or for cloud condensation nuclei measured at the PE station in the austral summer. [ABSTRACT FROM AUTHOR]

Published

2019

4. Measurements of aerosol and CCN properties in the Mackenzie River delta (Canadian Arctic) during spring-summer transition in May 2014.

Author

Herenz, Paul, Wex, Heike, Henning, Silvia, Kristensen, Thomas Bjerring, Rubach, Florian, Roth, Anja, Borrmann, Stephan, Bozem, Heiko, Schulz, Hannes, and Stratmann, Frank

Subjects

ATMOSPHERIC aerosols, HAZE, INDUSTRIAL pollution, ATMOSPHERIC chemistry

Abstract

Within the framework of the RACEPAC (Radiation-Aerosol-Cloud Experiment in the Arctic Circle) project, the Arctic aerosol, arriving at a ground-based station in Tuktoyaktuk (Mackenzie River delta area, Canada), was characterized during a period of 3 weeks in May 2014. Basic meteorological parameters and particle number size distributions (PNSDs) were observed and two distinct types of air masses were found. One type were typical Arctic haze air masses, termed accumulation-type air masses, characterized by a monomodal PNSD with a pronounced accumulation mode at sizes above 100 nm. These air masses were observed during a period when back trajectories indicate an air mass origin in the north-east of Canada. The other air mass type is characterized by a bimodal PNSD with a clear minimum around 90nm and with an Aitken mode consisting of freshly formed aerosol particles. Back trajectories indicate that these air masses, termed Aitken-type air masses, originated from the North Pacific. In addition, the application of the PSCF receptor model shows that air masses with their origin in active fire areas in central Canada and Siberia, in areas of industrial anthropogenic pollution (Norilsk and Prudhoe Bay Oil Field) and the north-west Pacific have enhanced total particle number concentrations (NCN). Generally, NCN ranged from 20 to 500 cm-3, while cloud condensation nuclei (CCN) number concentrations were found to cover a range from less than 10 up to 250 cm-3 for a supersaturation (SS) between 0.1 and 0.7 %. The hygroscopicity parameter κ of the CCN was determined to be 0.23 on average and variations in κ were largely attributed to measurement uncertainties. Furthermore, simultaneous PNSD measurements at the ground station and on the Polar 6 research aircraft were performed. We found a good agreement of ground-based PNSDs with those measured between 200 and 1200 m. During two of the four overflights, particle number concentrations at 3000m were found to be up to 20 times higher than those measured below 2000 m; for one of these two flights, PNSDs measured above 2000m showed a different shape than those measured at lower altitudes. This is indicative of long-range transport from lower latitudes into the Arctic that can advect aerosol from different regions in different heights. [ABSTRACT FROM AUTHOR]

Published

2018

5. Aerosol arriving on the Caribbean island of Barbados: physical properties and origin.

Author

Wex, Heike, Dieckmann, Katrin, Roberts, Greg C., Conrath, Thomas, Izaguirre, Miguel A., Hartmann, Susan, Herenz, Paul, Schäfer, Michael, Ditas, Florian, Schmeissner, Tina, Henning, Silvia, Wehner, Birgit, Siebert, Holger, and Stratmann, Frank

Subjects

ATMOSPHERIC aerosols, ATMOSPHERIC boundary layer, AIR masses, PARTICULATE matter

Abstract

The marine aerosol arriving at Barbados (Ragged Point) was characterized during two 3-week long measurement periods in November 2010 and April 2011, in the context of the measurement campaign CARRIBA (Cloud, Aerosol, Radiation and tuRbulence in the trade wInd regime over BArbados). Through a comparison between groundbased and airborne measurements it was shown that the former are representative of the marine boundary layer at least up to cloud base. In general, total particle number concentrations (Ntotal) ranged from as low as 100 up to 800 cm-3, while number concentrations for cloud condensation nuclei (NCCN) at a supersaturation of 0.26% ranged from some 10 to 600 cm-3. Ntotal and NCCCN depended on the air mass origin. Three distinct types of air masses were found. One type showed elevated values for both Ntotal and NCCCN and could be attributed to long-range transport from Africa, by which biomass burning particles from the Sahel region and/or mineral dust particles from the Sahara were advected. The second and third type both had values for NCCCN below 200 cm-3 and a clear minimum in the particle number size distribution (NSD) around 70 to 80 nm (Hoppel minimum). While for one of these two types the accumulation mode was dominating (albeit less so than for air masses advected from Africa), the Aitken mode dominated the other and contributed more than 50% of all particles. These Aitken mode particles likely were formed by new particle formation no more than 3 days prior to the measurements. Hygroscopicity of particles in the CCN size range was determined from CCN measurements to be κ =0.66 on average, which suggests that these particles contain mainly sulfate and do not show a strong influence from organic material, which might generally be the case for the months during which measurements were made. The average κ could be used to derive NCCCN from measured number size distributions, showing that this is a valid approach to obtain NCCCN. Although the total particulate mass sampled on filters was found to be dominated by Na+ and Cl-, this was found to be contributed by a small number of large particles (>500 nm, mostly even in the super-micron size range). Based on a three-modal fit, a sea spray mode observed in the NSDs was found to contribute 90% to the total particulate mass but only 4 to 10% to Ntotal and up to 15% to NCCCN. This is in accordance with finding no correlation between Ntotal and wind speed. [ABSTRACT FROM AUTHOR]

Published

2016

6. Arctic haze over Central Europe.

Author

HEINTZENBERG, JOST, TUCH, THOMAS, WEHNER, BIRGIT, WIEDENSOHLER, ALFRED, WEX, HEIKE, ANSMANN, ALBERT, MATTIS, INA, MÜLLER, DETLEF, WENDISCH, MANFRED, ECKHARDT, SABINE, and STOHL, ANDREAS

Subjects

HAZE, ATMOSPHERIC aerosols, PARTICLES

Abstract

ABSTRACT An extraordinary aerosol situation over Leipzig, Germany in April 2002 was investigated with a comprehensive set of ground-based volumetric and columnar aerosol data, combined with aerosol profiles from lidar, meteorological data from radiosondes and air mass trajectory calculations. Air masses were identified to stem from the Arctic, partly influenced by the greater Moscow region. An evaluation of ground-based measurements of aerosol size distributions during these periods showed that the number concentrations below about 70 nm in diameter were below respective long-term average data, while number, surface and volume concentrations of the particles larger than about 70 nm in diameter were higher than the long-term averages. The lidar aerosol profiles showed that the imported aerosol particles were present up to about 3 km altitude. The particle optical depth was up to 0.45 at 550 nm wavelength. With a one-dimensional spectral radiative transfer model top of the atmosphere (TOA) radiative forcing of the aerosol layer was estimated for a period with detailed vertical information. Solar aerosol radiative forcing values between -23 and -38 W m-2 were calculated, which are comparable to values that have been reported in heavily polluted continental plumes outside the respective source regions. The present report adds weight to previous findings of aerosol import to Europe, pointing to the need for attributing the three-dimensional aerosol burden to natural and anthropogenic sources as well as to aerosol imports from adjacent or distant source regions. In the present case, the transport situation is further complicated by forward trajectories, indicating that some of the observed Arctic haze may have originated in Central Europe. This aerosol was transported to the European Arctic before being re-imported in the modified and augmented form to its initial source region. [ABSTRACT FROM AUTHOR]

Published

2003

7. Connecting in-situ measurements of Ice Nucleating Particles in air and in ocean and cloud water for the region of the Cape Verde islands.

Author

Wex, Heike, Gong, Xianda, van Pinxteren, Manuela, Triesch, Nadja, Stolle, Christian, and Stratmann, Frank

Subjects

*CLOUD droplets, *SEAWATER, *CLOUD condensation nuclei, *ATMOSPHERIC chemistry, *SEA surface microlayer, *ATMOSPHERIC aerosols, *ICE, *SEA ice

Abstract

Ice nucleating particles (INP) in the troposphere can form ice in clouds via heterogeneous ice nucleation. Number concentrations of ice in clouds significantly affect cloud lifetime, the formation of precipitation and radiative properties. Still up to date, atmospheric number concentrations of INP are not well characterized and although there is some understanding of their sources, it is not known to which extend different sources contribute, nor if all sources are known. In this work, we are examining properties of INP that are known to occur in the oceanic sea surface microlayer (SML) and in bulk seawater, as well as the contribution of sea spray aerosol (SSA) to INP in clouds.The measurements to be presented here were carried out from 13 September to 12 October 2017 at Cape Verde. Besides for a thorough analysis of the atmospheric aerosol, samples collected for INP analysis include: bulk seawater and SML from the ocean upwind of the island; polycarbonate filter samples of atmospheric aerosol, collected on a tower installed at the island shore and on a 700 m high mountain top; cloud water collected during cloud events on the mountain top. INP concentrations were measured offline with two types of cold stages, based on well known techniques (see Chen et al., 2018), yielding results in the temperature range from roughly -5°C to -25°C.There were two main findings. Firstly, both enrichment and depletion of INP in the SML were observed compared to the bulk seawater, with an enrichment factor (EF) of INP number concentrations at -22 °C varying from 0.58 to 3.88. Secondly, the INP concentrations of the cloud water were around one order of magnitude higher than those of the SML and bulk seawater. When accounting for measured aerosol parameters (concentrations of total particles and cloud condensation nuclei) and assuming cloud droplet sizes in a range from 5 to 20 micrometer, it can be estimated that only a low fraction of all atmospheric INP were from the SSA.The authors acknowledge the Leibniz Association SAW funding for the MarParCloud project, SAW-2016-TROPOS-2.Literature: Chen, Jie, et al. "Ice-nucleating particle concentrations unaffected by urban air pollution in Beijing, China." Atmospheric Chemistry and Physics 18.5 (2018): 3523-3539. [ABSTRACT FROM AUTHOR]

Published

2019