Your search keyword '"Massling, A."' showing total 899 results

1. Widespread detection of chlorine oxyacids in the Arctic atmosphere

Author

Tham, Yee Jun, Sarnela, Nina, Iyer, Siddharth, Li, Qinyi, Angot, Hélène, Quéléver, Lauriane L. J., Beck, Ivo, Laurila, Tiia, Beck, Lisa J., Boyer, Matthew, Carmona-García, Javier, Borrego-Sánchez, Ana, Roca-Sanjuán, Daniel, Peräkylä, Otso, Thakur, Roseline C., He, Xu-Cheng, Zha, Qiaozhi, Howard, Dean, Blomquist, Byron, Archer, Stephen D., Bariteau, Ludovic, Posman, Kevin, Hueber, Jacques, Helmig, Detlev, Jacobi, Hans-Werner, Junninen, Heikki, Kulmala, Markku, Mahajan, Anoop S., Massling, Andreas, Skov, Henrik, Sipilä, Mikko, Francisco, Joseph S., Schmale, Julia, Jokinen, Tuija, and Saiz-Lopez, Alfonso

Published

2023

2. Impact of 2020 COVID-19 lockdowns on particulate air pollution across Europe

Author

J.-P. Putaud, E. Pisoni, A. Mangold, C. Hueglin, J. Sciare, M. Pikridas, C. Savvides, J. Ondracek, S. Mbengue, A. Wiedensohler, K. Weinhold, M. Merkel, L. Poulain, D. van Pinxteren, H. Herrmann, A. Massling, C. Nordstroem, A. Alastuey, C. Reche, N. Pérez, S. Castillo, M. Sorribas, J. A. Adame, T. Petaja, K. Lehtipalo, J. Niemi, V. Riffault, J. F. de Brito, A. Colette, O. Favez, J.-E. Petit, V. Gros, M. I. Gini, S. Vratolis, K. Eleftheriadis, E. Diapouli, H. Denier van der Gon, K. E. Yttri, and W. Aas

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

To fight against the first wave of coronavirus disease 2019 (COVID-19) in 2020, lockdown measures were implemented in most European countries. These lockdowns had well-documented effects on human mobility. We assessed the impact of the lockdown implementation and relaxation on air pollution by comparing daily particulate matter (PM), nitrogen dioxide (NO2) and ozone (O3) concentrations, as well as particle number size distributions (PNSDs) and particle light absorption coefficient in situ measurement data, with values that would have been expected if no COVID-19 epidemic had occurred at 28 sites across Europe for the period 17 February–31 May 2020. Expected PM, NO2 and O3 concentrations were calculated from the 2020 Copernicus Atmosphere Monitoring Service (CAMS) ensemble forecasts, combined with 2019 CAMS ensemble forecasts and measurement data. On average, lockdown implementations did not lead to a decrease in PM2.5 mass concentrations at urban sites, while relaxations resulted in a +26 ± 21 % rebound. The impacts of lockdown implementation and relaxation on NO2 concentrations were more consistent (−29 ± 17 and +31 ± 30 %, respectively). The implementation of the lockdown measures also induced statistically significant increases in O3 concentrations at half of all sites (+13 % on average). An enhanced oxidising capacity of the atmosphere could have boosted the production of secondary aerosol at those places. By comparison with 2017–2019 measurement data, a significant change in the relative contributions of wood and fossil fuel burning to the concentration of black carbon during the lockdown was detected at 7 out of 14 sites. The contribution of particles smaller than 70 nm to the total number of particles significantly also changed at most of the urban sites, with a mean decrease of −7 ± 5 % coinciding with the lockdown implementation. Our study shows that the response of PM2.5 and PM10 mass concentrations to lockdown measures was not systematic at various sites across Europe for multiple reasons, the relationship between road traffic intensity and particulate air pollution being more complex than expected.

Published

2023

3. Modelling wintertime sea-spray aerosols under Arctic haze conditions

Author

E. Ioannidis, K. S. Law, J.-C. Raut, L. Marelle, T. Onishi, R. M. Kirpes, L. M. Upchurch, T. Tuch, A. Wiedensohler, A. Massling, H. Skov, P. K. Quinn, and K. A. Pratt

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Anthropogenic and natural emissions contribute to enhanced concentrations of aerosols in the Arctic winter and early spring, with most attention being paid to anthropogenic aerosols that contribute to so-called Arctic haze. Less-well-studied wintertime sea-spray aerosols (SSAs) under Arctic haze conditions are the focus of this study, since they can make an important contribution to wintertime Arctic aerosol abundances. Analysis of field campaign data shows evidence for enhanced local sources of SSAs, including marine organics at Utqiaġvik (formerly known as Barrow) in northern Alaska, United States, during winter 2014. Models tend to underestimate sub-micron SSAs and overestimate super-micron SSAs in the Arctic during winter, including the base version of the Weather Research Forecast coupled with Chemistry (WRF-Chem) model used here, which includes a widely used SSA source function based on Gong et al. (1997). Quasi-hemispheric simulations for winter 2014 including updated wind speed and sea-surface temperature (SST) SSA emission dependencies and sources of marine sea-salt organics and sea-salt sulfate lead to significantly improved model performance compared to observations at remote Arctic sites, notably for coarse-mode sodium and chloride, which are reduced. The improved model also simulates more realistic contributions of SSAs to inorganic aerosols at different sites, ranging from 20 %–93 % in the observations. Two-thirds of the improved model performance is from the inclusion of the dependence on SSTs. The simulation of nitrate aerosols is also improved due to less heterogeneous uptake of nitric acid on SSAs in the coarse mode and related increases in fine-mode nitrate. This highlights the importance of interactions between natural SSAs and inorganic anthropogenic aerosols that contribute to Arctic haze. Simulation of organic aerosols and the fraction of sea-salt sulfate are also improved compared to observations. However, the model underestimates episodes with elevated observed concentrations of SSA components and sub-micron non-sea-salt sulfate at some Arctic sites, notably at Utqiaġvik. Possible reasons are explored in higher-resolution runs over northern Alaska for periods corresponding to the Utqiaġvik field campaign in January and February 2014. The addition of a local source of sea-salt marine organics, based on the campaign data, increases modelled organic aerosols over northern Alaska. However, comparison with previous available data suggests that local natural sources from open leads, as well as local anthropogenic sources, are underestimated in the model. Missing local anthropogenic sources may also explain the low modelled (sub-micron) non-sea-salt sulfate at Utqiaġvik. The introduction of a higher wind speed dependence for sub-micron SSA emissions, also based on Arctic data, reduces biases in modelled sub-micron SSAs, while sea-ice fractions, including open leads, are shown to be an important factor controlling modelled super-micron, rather than sub-micron, SSAs over the north coast of Alaska. The regional results presented here show that modelled SSAs are more sensitive to wind speed dependence but that realistic modelling of sea-ice distributions is needed for the simulation of local SSAs, including marine organics. This study supports findings from the Utqiaġvik field campaign that open leads are the primary source of fresh and aged SSAs, including marine organic aerosols, during wintertime at Utqiaġvik; these findings do not suggest an influence from blowing snow and frost flowers. To improve model simulations of Arctic wintertime aerosols, new field data on processes that influence wintertime SSA production, in particular for fine-mode aerosols, are needed as is improved understanding about possible local anthropogenic sources.

Published

2023

4. Composition and mixing state of individual aerosol particles from northeast Greenland and Svalbard in the Arctic during spring 2018

Author

Adachi, Kouji, Tobo, Yutaka, Oshima, Naga, Yoshida, Atsushi, Ohata, Sho, Krejci, Radovan, Massling, Andreas, Skov, Henrik, and Koike, Makoto

Published

2023

5. Measurement report: High Arctic aerosol hygroscopicity at sub- and supersaturated conditions during spring and summer

Author

A. Massling, R. Lange, J. B. Pernov, U. Gosewinkel, L.-L. Sørensen, and H. Skov

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Aerosol hygroscopic growth and cloud droplet formation influence the radiation transfer budget of the atmosphere and thereby the climate. In the Arctic, these aerosol properties may have a more pronounced effect on the climate compared to the midlatitudes. Hygroscopic growth and cloud condensation nuclei (CCN) concentrations of high Arctic aerosols were measured during two field studies in the spring and summer of 2016. The study site was the Villum Research Station (Villum) at Station Nord in the northeastern region of Greenland. Aerosol hygroscopic growth was measured with a hygroscopic tandem differential mobility analyzer (HTDMA) over a total of 23 d, and CCN concentrations were measured over a period of 95 d. Continuous particle number size distributions were recorded, facilitating calculations of aerosol CCN activation diameters and aerosol κ values. In spring, average CCN concentrations, at supersaturations (SSs) of 0.1 % to 0.3 %, ranged from 53.7 to 85.3 cm−3, with critical activation diameters ranging from 130.2 to 80.2 nm and κCCN ranging from 0.28–0.35. In summer, average CCN concentrations were 20.8 to 47.6 cm−3, while critical activation diameters and κCCN were from 137.1 to 76.7 nm and 0.23–0.35, respectively. Mean particle hygroscopic growth factors ranged from 1.60 to 1.75 at 90 % relative humidity in spring, while values between 1.47 and 1.67 were observed in summer depending on the initial dry size. Although the summer aerosol number size distributions were characterized by frequent new particle formation events, the CCN population at cloud-relevant supersaturations was determined by accumulation-mode aerosols.

Published

2023

6. Ice-nucleating particles in northern Greenland: annual cycles, biological contribution and parameterizations

Author

K. C. H. Sze, H. Wex, M. Hartmann, H. Skov, A. Massling, D. Villanueva, and F. Stratmann

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Ice-nucleating particles (INPs) can initiate ice formation in clouds at temperatures above −38 ∘C through heterogeneous ice nucleation. As a result, INPs affect cloud microphysical and radiative properties, cloud lifetime, and precipitation behavior and thereby ultimately the Earth's climate. Yet, little is known regarding the sources, abundance and properties of INPs, especially in remote regions such as the Arctic. In this study, 2-year-long INP measurements (from July 2018 to September 2020) at Villum Research Station in northern Greenland are presented. A low-volume filter sampler was deployed to collect filter samples for offline INP analysis. An annual cycle of INP concentration (NINP) was observed, and the fraction of heat-labile INPs was found to be higher in months with low to no snow cover and lower in months when the surface was well covered in snow (> 0.8 m). Samples were categorized into three different types based only on the slope of their INP spectra, namely into summer, winter and mix type. For each of the types a temperature-dependent INP parameterization was derived, clearly different depending on the time of the year. Winter and summer types occurred only during their respective seasons and were seen 60 % of the time. The mixed type occurred in the remaining 40 % of the time throughout the year. April, May and November were found to be transition months. A case study comparing April 2019 and April 2020 was performed. The month of April was selected because a significant difference in NINP was observed during these two periods, with clearly higher NINP in April 2020. In parallel to the observed differences in NINP, also a higher cloud-ice fraction was observed in satellite data for April 2020, compared to April 2019. NINP in the case study period revealed no clear dependency on either meteorological parameters or different surface types which were passed by the collected air masses. Overall, the results suggest that the coastal regions of Greenland were the main sources of INPs in April 2019 and 2020, most likely including both local terrestrial and marine sources.

Published

2023

7. Widespread detection of chlorine oxyacids in the Arctic atmosphere

Author

Yee Jun Tham, Nina Sarnela, Siddharth Iyer, Qinyi Li, Hélène Angot, Lauriane L. J. Quéléver, Ivo Beck, Tiia Laurila, Lisa J. Beck, Matthew Boyer, Javier Carmona-García, Ana Borrego-Sánchez, Daniel Roca-Sanjuán, Otso Peräkylä, Roseline C. Thakur, Xu-Cheng He, Qiaozhi Zha, Dean Howard, Byron Blomquist, Stephen D. Archer, Ludovic Bariteau, Kevin Posman, Jacques Hueber, Detlev Helmig, Hans-Werner Jacobi, Heikki Junninen, Markku Kulmala, Anoop S. Mahajan, Andreas Massling, Henrik Skov, Mikko Sipilä, Joseph S. Francisco, Julia Schmale, Tuija Jokinen, and Alfonso Saiz-Lopez

Subjects

Science

Abstract

Observations are reported of HClO3 and HClO4 in the atmosphere and their widespread occurrence over the pan-Arctic during spring, providing further insights into atmospheric chlorine cycling in the polar environment.

Published

2023

8. Collective geographical ecoregions and precursor sources driving Arctic new particle formation

Author

J. Brean, D. C. S. Beddows, R. M. Harrison, C. Song, P. Tunved, J. Ström, R. Krejci, E. Freud, A. Massling, H. Skov, E. Asmi, A. Lupi, and M. Dall'Osto

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The Arctic is a rapidly changing ecosystem, with complex ice–ocean–atmosphere feedbacks. An important process is new particle formation (NPF), from gas-phase precursors, which provides a climate forcing effect. NPF has been studied comprehensively at different sites in the Arctic, ranging from those in the High Arctic and those at Svalbard to those in the continental Arctic, but no harmonised analysis has been performed on all sites simultaneously, with no calculations of key NPF parameters available for some sites. Here, we analyse the formation and growth of new particles from six long-term ground-based stations in the Arctic (Alert, Villum, Tiksi, Zeppelin Mountain, Gruvebadet, and Utqiaġvik). Our analysis of particle formation and growth rates in addition to back-trajectory analysis shows a summertime maxima in the frequency of NPF and particle formation rate at all sites, although the mean frequency and particle formation rates themselves vary greatly between sites, with the highest at Svalbard and lowest in the High Arctic. The summertime growth rate, condensational sinks, and vapour source rates show a slight bias towards the southernmost sites, with vapour source rates varying by around an order of magnitude between the northernmost and southernmost sites. Air masses back-trajectories during NPF at these northernmost sites are associated with large areas of sea ice and snow, whereas events at Svalbard are associated with more sea ice and ocean regions. Events at the southernmost sites are associated with large areas of land and sea ice. These results emphasise how understanding the geographical variation in surface type across the Arctic is key to understanding secondary aerosol sources and providing a harmonised analysis of NPF across the Arctic.

Published

2023

9. Air pollution and myocardial infarction; effect modification by sociodemographic and environmental factors. A cohort study from Denmark

Author

Poulsen, Aslak Harbo, Sørensen, Mette, Hvidtfeldt, Ulla A., Frohn, Lise M., Ketzel, Matthias, Christensen, Jesper H., Brandt, Jørgen, Massling, Andreas, Khan, Jibran, Lassen, Christina Funch, and Raaschou-Nielsen, Ole

Published

2023

10. A full year of aerosol size distribution data from the central Arctic under an extreme positive Arctic Oscillation: insights from the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition

Author

M. Boyer, D. Aliaga, J. B. Pernov, H. Angot, L. L. J. Quéléver, L. Dada, B. Heutte, M. Dall'Osto, D. C. S. Beddows, Z. Brasseur, I. Beck, S. Bucci, M. Duetsch, A. Stohl, T. Laurila, E. Asmi, A. Massling, D. C. Thomas, J. K. Nøjgaard, T. Chan, S. Sharma, P. Tunved, R. Krejci, H. C. Hansson, F. Bianchi, K. Lehtipalo, A. Wiedensohler, K. Weinhold, M. Kulmala, T. Petäjä, M. Sipilä, J. Schmale, and T. Jokinen

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The Arctic environment is rapidly changing due to accelerated warming in the region. The warming trend is driving a decline in sea ice extent, which thereby enhances feedback loops in the surface energy budget in the Arctic. Arctic aerosols play an important role in the radiative balance and hence the climate response in the region, yet direct observations of aerosols over the Arctic Ocean are limited. In this study, we investigate the annual cycle in the aerosol particle number size distribution (PNSD), particle number concentration (PNC), and black carbon (BC) mass concentration in the central Arctic during the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition. This is the first continuous, year-long data set of aerosol PNSD ever collected over the sea ice in the central Arctic Ocean. We use a k-means cluster analysis, FLEXPART simulations, and inverse modeling to evaluate seasonal patterns and the influence of different source regions on the Arctic aerosol population. Furthermore, we compare the aerosol observations to land-based sites across the Arctic, using both long-term measurements and observations during the year of the MOSAiC expedition (2019–2020), to investigate interannual variability and to give context to the aerosol characteristics from within the central Arctic. Our analysis identifies that, overall, the central Arctic exhibits typical seasonal patterns of aerosols, including anthropogenic influence from Arctic haze in winter and secondary aerosol processes in summer. The seasonal pattern corresponds to the global radiation, surface air temperature, and timing of sea ice melting/freezing, which drive changes in transport patterns and secondary aerosol processes. In winter, the Norilsk region in Russia/Siberia was the dominant source of Arctic haze signals in the PNSD and BC observations, which contributed to higher accumulation-mode PNC and BC mass concentrations in the central Arctic than at land-based observatories. We also show that the wintertime Arctic Oscillation (AO) phenomenon, which was reported to achieve a record-breaking positive phase during January–March 2020, explains the unusual timing and magnitude of Arctic haze across the Arctic region compared to longer-term observations. In summer, the aerosol PNCs of the nucleation and Aitken modes are enhanced; however, concentrations were notably lower in the central Arctic over the ice pack than at land-based sites further south. The analysis presented herein provides a current snapshot of Arctic aerosol processes in an environment that is characterized by rapid changes, which will be crucial for improving climate model predictions, understanding linkages between different environmental processes, and investigating the impacts of climate change in future Arctic aerosol studies.

Published

2023

11. Short-term exposure to ultrafine particles and mortality and hospital admissions due to respiratory and cardiovascular diseases in Copenhagen, Denmark

Author

Bergmann, Marie L., Andersen, Zorana J., Massling, Andreas, Kindler, Paula A., Loft, Steffen, Amini, Heresh, Cole-Hunter, Thomas, Guo, Yuming, Maric, Matija, Nordstrøm, Claus, Taghavi, Mahmood, Tuffier, Stéphane, So, Rina, Zhang, Jiawei, and Lim, Youn-Hee

Published

2023

12. Hygroscopicity and CCN potential of DMS-derived aerosol particles

Author

B. Rosati, S. Isokääntä, S. Christiansen, M. M. Jensen, S. P. Moosakutty, R. Wollesen de Jonge, A. Massling, M. Glasius, J. Elm, A. Virtanen, and M. Bilde

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Dimethyl sulfide (DMS) is emitted by phytoplankton species in the oceans and constitutes the largest source of naturally emitted sulfur to the atmosphere. The climate impact of secondary particles, formed through the oxidation of DMS by hydroxyl radicals, is still elusive. This study investigates the hygroscopicity and cloud condensation nuclei activity of such particles and discusses the results in relation to their chemical composition. We show that mean hygroscopicity parameters, κ, during an experiment for particles of 80 nm in diameter range from 0.46 to 0.52 or higher, as measured at both sub- and supersaturated water vapour conditions. Ageing of the particles leads to an increase in κ from, for example, 0.50 to 0.58 over the course of 3 h (Exp. 7). Aerosol mass spectrometer measurements from this study indicate that this change most probably stems from a change in chemical composition leading to slightly higher fractions of ammonium sulfate compared to methanesulfonic acid (MSA) within the particles with ageing time. Lowering the temperature to 258 K increases κ slightly, particularly for small particles. These κ values are well comparable to previously reported model values for MSA or mixtures between MSA and ammonium sulfate. Particle nucleation and growth rates suggest a clear temperature dependence, with slower rates at cold temperatures. Quantum chemical calculations show that gas-phase MSA clusters are predominantly not hydrated, even at high humidity conditions, indicating that their gas-phase chemistry should be independent of relative humidity.

Published

2022

13. Comparison of particle number size distribution trends in ground measurements and climate models

Author

V. Leinonen, H. Kokkola, T. Yli-Juuti, T. Mielonen, T. Kühn, T. Nieminen, S. Heikkinen, T. Miinalainen, T. Bergman, K. Carslaw, S. Decesari, M. Fiebig, T. Hussein, N. Kivekäs, R. Krejci, M. Kulmala, A. Leskinen, A. Massling, N. Mihalopoulos, J. P. Mulcahy, S. M. Noe, T. van Noije, F. M. O'Connor, C. O'Dowd, D. Olivie, J. B. Pernov, T. Petäjä, Ø. Seland, M. Schulz, C. E. Scott, H. Skov, E. Swietlicki, T. Tuch, A. Wiedensohler, A. Virtanen, and S. Mikkonen

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Despite a large number of studies, out of all drivers of radiative forcing, the effect of aerosols has the largest uncertainty in global climate model radiative forcing estimates. There have been studies of aerosol optical properties in climate models, but the effects of particle number size distribution need a more thorough inspection. We investigated the trends and seasonality of particle number concentrations in nucleation, Aitken, and accumulation modes at 21 measurement sites in Europe and the Arctic. For 13 of those sites, with longer measurement time series, we compared the field observations with the results from five climate models, namely EC-Earth3, ECHAM-M7, ECHAM-SALSA, NorESM1.2, and UKESM1. This is the first extensive comparison of detailed aerosol size distribution trends between in situ observations from Europe and five earth system models (ESMs). We found that the trends of particle number concentrations were mostly consistent and decreasing in both measurements and models. However, for many sites, climate models showed weaker decreasing trends than the measurements. Seasonal variability in measured number concentrations, quantified by the ratio between maximum and minimum monthly number concentration, was typically stronger at northern measurement sites compared to other locations. Models had large differences in their seasonal representation, and they can be roughly divided into two categories: for EC-Earth and NorESM, the seasonal cycle was relatively similar for all sites, and for other models the pattern of seasonality varied between northern and southern sites. In addition, the variability in concentrations across sites varied between models, some having relatively similar concentrations for all sites, whereas others showed clear differences in concentrations between remote and urban sites. To conclude, although all of the model simulations had identical input data to describe anthropogenic mass emissions, trends in differently sized particles vary among the models due to assumptions in emission sizes and differences in how models treat size-dependent aerosol processes. The inter-model variability was largest in the accumulation mode, i.e. sizes which have implications for aerosol–cloud interactions. Our analysis also indicates that between models there is a large variation in efficiency of long-range transportation of aerosols to remote locations. The differences in model results are most likely due to the more complex effect of different processes instead of one specific feature (e.g. the representation of aerosol or emission size distributions). Hence, a more detailed characterization of microphysical processes and deposition processes affecting the long-range transport is needed to understand the model variability.

Published

2022

14. Increased aerosol concentrations in the High Arctic attributable to changing atmospheric transport patterns

Author

Jakob Boyd Pernov, David Beddows, Daniel Charles Thomas, Manuel Dall´Osto, Roy M. Harrison, Julia Schmale, Henrik Skov, and Andreas Massling

Subjects

Environmental sciences, GE1-350, Meteorology. Climatology, QC851-999

Abstract

Abstract The Arctic environment has changed profoundly in recent decades. Aerosol particles are involved in numerous feedback mechanisms in the Arctic, e.g., aerosol-cloud/radiation interactions, which have important climatic implications. To understand changes in different Arctic aerosol types and number concentrations, we have performed a trend analysis of particle number size distributions, their properties, and their associated air mass history at Villum Research Station, northeastern Greenland, from 2010 to 2018. We found that, during spring, the total/ultrafine mode number concentration and the time air masses spent over the open ocean is significantly increasing, which can be ascribed to transport patterns changing to more frequent arrival from the ice-free Greenland Sea. We found that, during summer, the total/ultrafine mode number concentration, the occurrence of the Nucleation cluster (i.e. newly formed particles from gas to particle conversion), and the time air masses spent over the open ocean is significantly increasing. This can also be attributed to changing transport patterns, here with air masses arriving more frequently from Baffin Bay. Finally, we found that, during autumn, the ultrafine number concentration and the occurrence of the Pristine cluster (i.e. clean, natural Arctic background conditions) is significantly increasing, which is likely due to increasing amounts of accumulated precipitation along the trajectory path and decreasing time air masses spent above the mixed layer, respectively. Our results demonstrate that changing circulation and precipitation patterns are the factors predominantly affecting the trends in aerosol particle number concentrations and the occurrence of different aerosol types in northeastern Greenland.

Published

2022

15. Model evaluation of short-lived climate forcers for the Arctic Monitoring and Assessment Programme: a multi-species, multi-model study

Author

C. H. Whaley, R. Mahmood, K. von Salzen, B. Winter, S. Eckhardt, S. Arnold, S. Beagley, S. Becagli, R.-Y. Chien, J. Christensen, S. M. Damani, X. Dong, K. Eleftheriadis, N. Evangeliou, G. Faluvegi, M. Flanner, J. S. Fu, M. Gauss, F. Giardi, W. Gong, J. L. Hjorth, L. Huang, U. Im, Y. Kanaya, S. Krishnan, Z. Klimont, T. Kühn, J. Langner, K. S. Law, L. Marelle, A. Massling, D. Olivié, T. Onishi, N. Oshima, Y. Peng, D. A. Plummer, O. Popovicheva, L. Pozzoli, J.-C. Raut, M. Sand, L. N. Saunders, J. Schmale, S. Sharma, R. B. Skeie, H. Skov, F. Taketani, M. A. Thomas, R. Traversi, K. Tsigaridis, S. Tsyro, S. Turnock, V. Vitale, K. A. Walker, M. Wang, D. Watson-Parris, and T. Weiss-Gibbons

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

While carbon dioxide is the main cause for global warming, modeling short-lived climate forcers (SLCFs) such as methane, ozone, and particles in the Arctic allows us to simulate near-term climate and health impacts for a sensitive, pristine region that is warming at 3 times the global rate. Atmospheric modeling is critical for understanding the long-range transport of pollutants to the Arctic, as well as the abundance and distribution of SLCFs throughout the Arctic atmosphere. Modeling is also used as a tool to determine SLCF impacts on climate and health in the present and in future emissions scenarios. In this study, we evaluate 18 state-of-the-art atmospheric and Earth system models by assessing their representation of Arctic and Northern Hemisphere atmospheric SLCF distributions, considering a wide range of different chemical species (methane, tropospheric ozone and its precursors, black carbon, sulfate, organic aerosol, and particulate matter) and multiple observational datasets. Model simulations over 4 years (2008–2009 and 2014–2015) conducted for the 2022 Arctic Monitoring and Assessment Programme (AMAP) SLCF assessment report are thoroughly evaluated against satellite, ground, ship, and aircraft-based observations. The annual means, seasonal cycles, and 3-D distributions of SLCFs were evaluated using several metrics, such as absolute and percent model biases and correlation coefficients. The results show a large range in model performance, with no one particular model or model type performing well for all regions and all SLCF species. The multi-model mean (mmm) was able to represent the general features of SLCFs in the Arctic and had the best overall performance. For the SLCFs with the greatest radiative impact (CH4, O3, BC, and SO42-), the mmm was within ±25 % of the measurements across the Northern Hemisphere. Therefore, we recommend a multi-model ensemble be used for simulating climate and health impacts of SLCFs. Of the SLCFs in our study, model biases were smallest for CH4 and greatest for OA. For most SLCFs, model biases skewed from positive to negative with increasing latitude. Our analysis suggests that vertical mixing, long-range transport, deposition, and wildfires remain highly uncertain processes. These processes need better representation within atmospheric models to improve their simulation of SLCFs in the Arctic environment. As model development proceeds in these areas, we highly recommend that the vertical and 3-D distribution of SLCFs be evaluated, as that information is critical to improving the uncertain processes in models.

Published

2022

16. A local marine source of atmospheric particles in the High Arctic

Author

Nøjgaard, J.K., Peker, L., Pernov, J.B., Johnson, M.S., Bossi, R., Massling, A., Lange, R., Nielsen, I.E., Prevot, A.S.H., Eriksson, A.C., Canonaco, F., and Skov, H.

Published

2022

17. Arctic observations and sustainable development goals – Contributions and examples from ERA-PLANET iCUPE data

Author

Noe, Steffen M., Tabakova, Ksenia, Mahura, Alexander, Lappalainen, Hanna K., Kosmale, Miriam, Heilimo, Jyri, Salzano, Roberto, Santoro, Mattia, Salvatori, Rosamaria, Spolaor, Andrea, Cairns, Warren, Barbante, Carlo, Pankratov, Fidel, Humbert, Angelika, Sonke, Jeroen E., Law, Kathy S., Onishi, Tatsuo, Paris, Jean-Daniel, Skov, Henrik, Massling, Andreas, Dommergue, Aurélien, Arshinov, Mikhail, Davydov, Denis, Belan, Boris, and Petäjä, Tuukka

Published

2022

18. Equal abundance of summertime natural and wintertime anthropogenic Arctic organic aerosols

Author

Moschos, Vaios, Dzepina, Katja, Bhattu, Deepika, Lamkaddam, Houssni, Casotto, Roberto, Daellenbach, Kaspar R., Canonaco, Francesco, Rai, Pragati, Aas, Wenche, Becagli, Silvia, Calzolai, Giulia, Eleftheriadis, Konstantinos, Moffett, Claire E., Schnelle-Kreis, Jürgen, Severi, Mirko, Sharma, Sangeeta, Skov, Henrik, Vestenius, Mika, Zhang, Wendy, Hakola, Hannele, Hellén, Heidi, Huang, Lin, Jaffrezo, Jean-Luc, Massling, Andreas, Nøjgaard, Jakob K., Petäjä, Tuukka, Popovicheva, Olga, Sheesley, Rebecca J., Traversi, Rita, Yttri, Karl Espen, Schmale, Julia, Prévôt, André S. H., Baltensperger, Urs, and El Haddad, Imad

Published

2022

19. Increased aerosol concentrations in the High Arctic attributable to changing atmospheric transport patterns

Author

Pernov, Jakob Boyd, Beddows, David, Thomas, Daniel Charles, Dall´Osto, Manuel, Harrison, Roy M., Schmale, Julia, Skov, Henrik, and Massling, Andreas

Published

2022

20. Pan-Arctic seasonal cycles and long-term trends of aerosol properties from 10 observatories

Author

J. Schmale, S. Sharma, S. Decesari, J. Pernov, A. Massling, H.-C. Hansson, K. von Salzen, H. Skov, E. Andrews, P. K. Quinn, L. M. Upchurch, K. Eleftheriadis, R. Traversi, S. Gilardoni, M. Mazzola, J. Laing, and P. Hopke

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Even though the Arctic is remote, aerosol properties observed there are strongly influenced by anthropogenic emissions from outside the Arctic. This is particularly true for the so-called Arctic haze season (January through April). In summer (June through September), when atmospheric transport patterns change, and precipitation is more frequent, local Arctic sources, i.e., natural sources of aerosols and precursors, play an important role. Over the last few decades, significant reductions in anthropogenic emissions have taken place. At the same time a large body of literature shows evidence that the Arctic is undergoing fundamental environmental changes due to climate forcing, leading to enhanced emissions by natural processes that may impact aerosol properties. In this study, we analyze 9 aerosol chemical species and 4 particle optical properties from 10 Arctic observatories (Alert, Kevo, Pallas, Summit, Thule, Tiksi, Barrow/Utqiaġvik, Villum, and Gruvebadet and Zeppelin Observatory – both at Ny-Ålesund Research Station) to understand changes in anthropogenic and natural aerosol contributions. Variables include equivalent black carbon, particulate sulfate, nitrate, ammonium, methanesulfonic acid, sodium, iron, calcium and potassium, as well as scattering and absorption coefficients, single scattering albedo and scattering Ångström exponent. First, annual cycles are investigated, which despite anthropogenic emission reductions still show the Arctic haze phenomenon. Second, long-term trends are studied using the Mann–Kendall Theil–Sen slope method. We find in total 41 significant trends over full station records, i.e., spanning more than a decade, compared to 26 significant decadal trends. The majority of significantly declining trends is from anthropogenic tracers and occurred during the haze period, driven by emission changes between 1990 and 2000. For the summer period, no uniform picture of trends has emerged. Twenty-six percent of trends, i.e., 19 out of 73, are significant, and of those 5 are positive and 14 are negative. Negative trends include not only anthropogenic tracers such as equivalent black carbon at Kevo, but also natural indicators such as methanesulfonic acid and non-sea-salt calcium at Alert. Positive trends are observed for sulfate at Gruvebadet. No clear evidence of a significant change in the natural aerosol contribution can be observed yet. However, testing the sensitivity of the Mann–Kendall Theil–Sen method, we find that monotonic changes of around 5 % yr−1 in an aerosol property are needed to detect a significant trend within one decade. This highlights that long-term efforts well beyond a decade are needed to capture smaller changes. It is particularly important to understand the ongoing natural changes in the Arctic, where interannual variability can be high, such as with forest fire emissions and their influence on the aerosol population. To investigate the climate-change-induced influence on the aerosol population and the resulting climate feedback, long-term observations of tracers more specific to natural sources are needed, as well as of particle microphysical properties such as size distributions, which can be used to identify changes in particle populations which are not well captured by mass-oriented methods such as bulk chemical composition.

Published

2022

21. The effect of the 2020 COVID-19 lockdown on atmospheric black carbon levels in northeastern Greenland

Author

Thomas, Daniel Charles, Christensen, Jesper H., Massling, Andreas, Pernov, Jakob Boyd, and Skov, Henrik

Published

2022

22. The optical properties and direct radiative forcing potential of atmospheric aerosols in Northeastern Greenland

Author

Thomas, Daniel Charles, primary, Beddows, David, additional, Pernov, Jakob Boyd, additional, Massling, Andreas, additional, Nøjgaard, Jakob Klenø, additional, Harrison, Roy M., additional, Dall'Osto, Manuel, additional, Močnik, Griša, additional, and Skov, Henrik, additional

Published

2024

23. Modelling ultrafine particle number concentrations at address resolution in Denmark from 1979 to 2018 - Part 2: Local and street scale modelling and evaluation

Author

Ketzel, Matthias, Frohn, Lise M., Christensen, Jesper H., Brandt, Jørgen, Massling, Andreas, Andersen, Christopher, Im, Ulas, Jensen, Steen Solvang, Khan, Jibran, Nielsen, Ole-Kenneth, Plejdrup, Marlene S., Manders, Astrid, Denier van der Gon, Hugo, Kumar, Prashant, and Raaschou-Nielsen, Ole

Published

2021

24. Modelling ultrafine particle number concentrations at address resolution in Denmark from 1979-2018 – Part 1: Regional and urban scale modelling and evaluation

Author

Frohn, Lise Marie, Ketzel, Matthias, Christensen, Jesper Heile, Brandt, Jørgen, Im, Ulas, Massling, Andreas, Andersen, Christopher, Plejdrup, Marlene Schmidt, Nielsen, Ole-Kenneth, Gon, Hugo Denier van der, Manders-Groot, Astrid, and Raaschou-Nielsen, Ole

Published

2021

25. Dynamics of gaseous oxidized mercury at Villum Research Station during the High Arctic summer

Author

J. B. Pernov, B. Jensen, A. Massling, D. C. Thomas, and H. Skov

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

While much research has been devoted to the subject of gaseous elemental mercury (GEM) and gaseous oxidized mercury (GOM) in the Arctic spring during atmospheric mercury depletion events, few studies have examined the behavior of GOM in the High Arctic summer. GOM, once deposited and incorporated into the ecosystem, can pose a threat to human and wildlife health, though there remain large uncertainties regarding the transformation, deposition, and assimilation of mercury into the food web. Therefore, to further our understanding of the dynamics of GOM in the High Arctic during the late summer, we performed measurements of GEM and GOM, along with meteorological parameters and atmospheric constituents, and utilized modeled air mass history during two summer campaigns in 2019 and 2020 at Villum Research Station (Villum) in northeastern Greenland. Seven events of enhanced GOM concentrations were identified and investigated in greater detail. In general, the common factors associated with event periods at ground level were higher levels of radiation and lower H2O mixing ratios, accumulated precipitation, and relative humidity (RH), although none were connected with cold temperatures. Non-event periods at ground level each displayed a different pattern in one or more parameters when compared to event periods. Generally, air masses during event periods for both campaigns were colder and drier, arrived from higher altitudes, and spent more time above the mixed layer and less time in a cloud compared to non-events, although some events deviated from this general pattern. Non-event air masses displayed a different pattern in one or more parameters when compared to event periods, although they were generally warmer and wetter and arrived from lower altitudes with little radiation. Coarse-mode aerosols were hypothesized to provide the heterogenous surface for halogen propagation during some of the events, while for others the source is unknown. While these general patterns were observed for event and non-event periods, analysis of individual events showed more specific origins. Five of the seven events were associated with air masses that experienced similar conditions: transported from the cold, dry, and sunlit free troposphere. However, two events experienced contrasting conditions, with air masses being warm and wet with surface layer contact under little radiation. Two episodes of extremely high levels of NCoarse and BC, which appear to originate from flaring emissions in Russia, did not contribute to enhanced GOM levels. This work aims to provide a better understanding of the dynamics of GOM during the High Arctic summer.

Published

2021

26. A phenomenology of new particle formation (NPF) at 13 European sites

Author

D. Bousiotis, F. D. Pope, D. C. S. Beddows, M. Dall'Osto, A. Massling, J. K. Nøjgaard, C. Nordstrøm, J. V. Niemi, H. Portin, T. Petäjä, N. Perez, A. Alastuey, X. Querol, G. Kouvarakis, N. Mihalopoulos, S. Vratolis, K. Eleftheriadis, A. Wiedensohler, K. Weinhold, M. Merkel, T. Tuch, and R. M. Harrison

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

New particle formation (NPF) events occur almost everywhere in the world and can play an important role as a particle source. The frequency and characteristics of NPF events vary spatially, and this variability is yet to be fully understood. In the present study, long-term particle size distribution datasets (minimum of 3 years) from 13 sites of various land uses and climates from across Europe were studied, and NPF events, deriving from secondary formation and not traffic-related nucleation, were extracted and analysed. The frequency of NPF events was consistently found to be higher at rural background sites, while the growth and formation rates of newly formed particles were higher at roadsides (though in many cases differences between the sites were small), underlining the importance of the abundance of condensable compounds of anthropogenic origin found there. The growth rate was higher in summer at all rural background sites studied. The urban background sites presented the highest uncertainty due to greater variability compared to the other two types of site. The origin of incoming air masses and the specific conditions associated with them greatly affect the characteristics of NPF events. In general, cleaner air masses present higher probability for NPF events, while the more polluted ones show higher growth rates. However, different patterns of NPF events were found, even at sites in close proximity (< 200 km), due to the different local conditions at each site. Region-wide events were also studied and were found to be associated with the same conditions as local events, although some variability was found which was associated with the different seasonality of the events at two neighbouring sites. NPF events were responsible for an increase in the number concentration of ultrafine particles of more than 400 % at rural background sites on the day of their occurrence. The degree of enhancement was less at urban sites due to the increased contribution of other sources within the urban environment. It is evident that, while some variables (such as solar radiation intensity, relative humidity, or the concentrations of specific pollutants) appear to have a similar influence on NPF events across all sites, it is impossible to predict the characteristics of NPF events at a site using just these variables, due to the crucial role of local conditions.

Published

2021

27. The impact of atmospheric oxidation on hygroscopicity and cloud droplet activation of inorganic sea spray aerosol

Author

Bernadette Rosati, Sigurd Christiansen, Anders Dinesen, Pontus Roldin, Andreas Massling, E. Douglas Nilsson, and Merete Bilde

Subjects

Medicine, Science

Abstract

Abstract Sea spray aerosol (SSA) contributes significantly to natural aerosol particle concentrations globally, in marine areas even dominantly. The potential changes of the omnipresent inorganic fraction of SSA due to atmospheric ageing is largely unexplored. In the atmosphere, SSA may exist as aqueous phase solution droplets or as dried solid or amorphous particles. We demonstrate that ageing of liquid NaCl and artificial sea salt aerosol by exposure to ozone and UV light leads to a substantial decrease in hygroscopicity and cloud activation potential of the dried particles of the same size. The results point towards surface reactions on the liquid aerosols that are more crucial for small particles and the formation of salt structures with water bound within the dried aerosols, termed hydrates. Our findings suggest an increased formation of hydrate forming salts during ageing and the presence of hydrates in dried SSA. Field observations indicate a reduced hygroscopic growth factor of sub-micrometre SSA in the marine atmosphere compared to fresh laboratory generated NaCl or sea salt of the same dry size, which is typically attributed to organic matter or sulphates. Aged inorganic sea salt offers an additional explanation for such a measured reduced hygroscopic growth factor and cloud activation potential.

Published

2021

28. Seasonal Variation of the Atmospheric Bacterial Community in the Greenlandic High Arctic Is Influenced by Weather Events and Local and Distant Sources

Author

Lasse Z. Jensen, Marianne Glasius, Sven-Erik Gryning, Andreas Massling, Kai Finster, and Tina Šantl-Temkiv

Subjects

bioaerosols, atmospheric bacterial community, Arctic haze, microbial activity, ice nucleation, Microbiology, QR1-502

Abstract

The Arctic is a hot spot for climate change with potentially large consequences on a global scale. Aerosols, including bioaerosols, are important players in regulating the heat balance through direct interaction with sunlight and indirectly, through inducing cloud formation. Airborne bacteria are the major bioaerosols with some species producing the most potent ice nucleating compounds known, which are implicated in the formation of ice in clouds. Little is known about the numbers and dynamics of airborne bacteria in the Arctic and even less about their seasonal variability. We collected aerosol samples and wet deposition samples in spring 2015 and summer 2016, at the Villum Research Station in Northeast Greenland. We used amplicon sequencing and qPCR targeting the 16S rRNA genes to assess the quantities and composition of the DNA and cDNA-level bacterial community. We found a clear seasonal variation in the atmospheric bacterial community, which is likely due to variable sources and meteorology. In early spring, the atmospheric bacterial community was dominated by taxa originating from temperate and Subarctic regions and arriving at the sampling site through long-range transport. We observed an efficient washout of the aerosolized bacterial cells during a snowstorm, which was followed by very low concentrations of bacteria in the atmosphere during the consecutive 4 weeks. We suggest that this is because in late spring, the long-range transport ceased, and the local sources which comprised only of ice and snow surfaces were weak resulting in low bacterial concentrations. This was supported by observed changes in the chemical composition of aerosols. In summer, the air bacterial community was confined to local sources such as soil, plant material and melting sea-ice. Aerosolized and deposited Cyanobacteria in spring had a high activity potential, implying their activity in the atmosphere or in surface snow. Overall, we show how the composition of bacterial aerosols in the high Arctic varies on a seasonal scale, identify their potential sources, demonstrate how their community sizes varies in time, investigate their diversity and determine their activity potential during and post Arctic haze.

Published

2022

29. The effect of meteorological conditions and atmospheric composition in the occurrence and development of new particle formation (NPF) events in Europe

Author

D. Bousiotis, J. Brean, F. D. Pope, M. Dall'Osto, X. Querol, A. Alastuey, N. Perez, T. Petäjä, A. Massling, J. K. Nøjgaard, C. Nordstrøm, G. Kouvarakis, S. Vratolis, K. Eleftheriadis, J. V. Niemi, H. Portin, A. Wiedensohler, K. Weinhold, M. Merkel, T. Tuch, and R. M. Harrison

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Although new particle formation (NPF) events have been studied extensively for some decades, the mechanisms that drive their occurrence and development are yet to be fully elucidated. Laboratory studies have done much to elucidate the molecular processes involved in nucleation, but this knowledge has yet to be conclusively linked to NPF events in the atmosphere. There is great difficulty in successful application of the results from laboratory studies to real atmospheric conditions due to the diversity of atmospheric conditions and observations found, as NPF events occur almost everywhere in the world without always following a clearly defined trend of frequency, seasonality, atmospheric conditions, or event development. The present study seeks common features in nucleation events by applying a binned linear regression over an extensive dataset from 16 sites of various types (combined dataset of 85 years from rural and urban backgrounds as well as roadside sites) in Europe. At most sites, a clear positive relation with the frequency of NPF events is found between the solar radiation intensity (up to R2=0.98), temperature (up to R2=0.98), and atmospheric pressure (up to R2=0.97), while relative humidity (RH) presents a negative relation (up to R2=0.95) with NPF event frequency, though exceptions were found among the sites for all the variables studied. Wind speed presents a less consistent relationship, which appears to be heavily affected by local conditions. While some meteorological variables (such as the solar radiation intensity and RH) appear to have a crucial effect on the occurrence and characteristics of NPF events, especially at rural sites, it appears that their role becomes less marked at higher average values. The analysis of chemical composition data presents interesting results. Concentrations of almost all chemical compounds studied (apart from O3) and the condensation sink (CS) have a negative relationship with NPF event frequency, though areas with higher average concentrations of SO2 had higher NPF event frequency. Particulate organic carbon (OC), volatile organic compounds (VOCs), and particulate-phase sulfate consistently had a positive relation with the growth rate of the newly formed particles. As with some meteorological variables, it appears that at increased concentrations of pollutants or the CS, their influence upon NPF frequency is reduced.

Published

2021

30. Model Evaluation of Short-Lived Climate Forcers for the Arctic Monitoring and Assessment Programme: A Multi-Species, Multi-Model Study

Author

Cynthia H Whaley, Rashed Mahmood, Knut von Salzen, Barbara Winter, Sabine Eckhardt, Stephen Arnold, Stephen Beagley, Silvia Becagli, Rong-You Chien, Jesper Christensen, Sujay Manish Damani, Xinyi Dong, Konstantinos Eleftheriadis, Nikolaos Evangeliou, Gregory S Faluvegi, Mark Flanner, Joshua S Fu, Michael Gauss, Fabio Giardi, Wanmin Gong, Jens Liengaard Hjorth, Lin Huang, Ulas Im, Yugo Kanaya, Srinath Krishnan, Zbigniew Klimont, Thomas Kuhn, Joakim Langner, Kathy S Law, Louis Marelle, Andreas Massling, Dirk Olivié, Tatsuo Onishi, Naga Oshima, Yiran Peng, David A Plummer, Olga Popovicheva, Luca Pozzoli, Jean-Christophe Raut, Maria Sand, Laura N Saunders, Julia Schmale, Sangeeta Sharma, Ragnhild Bieltvedt Skeie, Henrik Skov, Fumikazu Taketani, Manu A Thomas, Rita Traversi, Konstantinos Tsigaridis, Svetlana Tsyro, Steven T Turnock, Vito Vitale, Kaley A Walker, Minqi Wang, Duncan Watson Parris, and Tahya Weiss-Gibbons

Subjects

Meteorology And Climatology

Abstract

While carbon dioxide is the main cause for global warming, modeling short-lived climate forcers (SLCFs) such as methane, ozone, and particles in the Arctic allows us to simulate near-term climate and health impacts for a sensitive, pristine region that is warming at 3 times the global rate. Atmospheric modeling is critical for understanding the long-range transport of pollutants to the Arctic, as well as the abundance and distribution of SLCFs throughout the Arctic atmosphere. Modeling is also used as a tool to determine SLCF impacts on climate and health in the present and in future emissions scenarios. In this study, we evaluate 18 state-of-the-art atmospheric and Earth system models by assessing their representation of Arctic and Northern Hemisphere atmospheric SLCF distributions, considering a wide range of different chemical species (methane, tropospheric ozone and its precursors, black carbon, sulfate, organic aerosol, and particulate matter) and multiple observational datasets. Model simulations over 4 years (2008-2009 and 2014-2015) conducted for the 2022 Arctic Monitoring and Assessment Programme (AMAP) SLCF assessment report are thoroughly evaluated against satellite, ground, ship, and aircraft-based observations. The annual means, seasonal cycles, and 3-D distributions of SLCFs were evaluated using several metrics, such as absolute and percent model biases and correlation coefficients. The results show a large range in model performance, with no one particular model or model type performing well for all regions and all SLCF species. The multi-model mean (mmm) was able to represent the general features of SLCFs in the Arctic and had the best overall performance. For the SLCFs with the greatest radiative impact (CH4, 03, BC, and SO(sup 2-)(sub 4)), the mmm was within ±25 % of the measurements across the Northern Hemisphere. Therefore, we recommend a multi-model ensemble be used for simulating climate and health impacts of SLCFs. Of the SLCFs in our study, model biases were smallest for C"4 and greatest for OA. For most SLCFs, model biases skewed from positive to negative with increasing latitude. Our analysis suggests that vertical mixing, long-range transport, deposition, and wildfires remain highly uncertain processes. These processes need better representation within atmospheric models to improve their simulation of SLCFs in the Arctic environment. As model development proceeds in these areas, we highly recommend that the vertical and 3-D distribution of SLCFs be evaluated, as that information is critical to improving the uncertain processes in models.

Published

2022

31. Overview: Integrative and Comprehensive Understanding on Polar Environments (iCUPE) – concept and initial results

Author

T. Petäjä, E.-M. Duplissy, K. Tabakova, J. Schmale, B. Altstädter, G. Ancellet, M. Arshinov, Y. Balin, U. Baltensperger, J. Bange, A. Beamish, B. Belan, A. Berchet, R. Bossi, W. R. L. Cairns, R. Ebinghaus, I. El Haddad, B. Ferreira-Araujo, A. Franck, L. Huang, A. Hyvärinen, A. Humbert, A.-C. Kalogridis, P. Konstantinov, A. Lampert, M. MacLeod, O. Magand, A. Mahura, L. Marelle, V. Masloboev, D. Moisseev, V. Moschos, N. Neckel, T. Onishi, S. Osterwalder, A. Ovaska, P. Paasonen, M. Panchenko, F. Pankratov, J. B. Pernov, A. Platis, O. Popovicheva, J.-C. Raut, A. Riandet, T. Sachs, R. Salvatori, R. Salzano, L. Schröder, M. Schön, V. Shevchenko, H. Skov, J. E. Sonke, A. Spolaor, V. K. Stathopoulos, M. Strahlendorff, J. L. Thomas, V. Vitale, S. Vratolis, C. Barbante, S. Chabrillat, A. Dommergue, K. Eleftheriadis, J. Heilimo, K. S. Law, A. Massling, S. M. Noe, J.-D. Paris, A. S. H. Prévôt, I. Riipinen, B. Wehner, Z. Xie, and H. K. Lappalainen

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The role of polar regions is increasing in terms of megatrends such as globalization, new transport routes, demography, and the use of natural resources with consequent effects on regional and transported pollutant concentrations. We set up the ERA-PLANET Strand 4 project “iCUPE – integrative and Comprehensive Understanding on Polar Environments” to provide novel insights and observational data on global grand challenges with an Arctic focus. We utilize an integrated approach combining in situ observations, satellite remote sensing Earth observations (EOs), and multi-scale modeling to synthesize data from comprehensive long-term measurements, intensive campaigns, and satellites to deliver data products, metrics, and indicators to stakeholders concerning the environmental status, availability, and extraction of natural resources in the polar areas. The iCUPE work consists of thematic state-of-the-art research and the provision of novel data in atmospheric pollution, local sources and transboundary transport, the characterization of arctic surfaces and their changes, an assessment of the concentrations and impacts of heavy metals and persistent organic pollutants and their cycling, the quantification of emissions from natural resource extraction, and the validation and optimization of satellite Earth observation (EO) data streams. In this paper we introduce the iCUPE project and summarize initial results arising out of the integration of comprehensive in situ observations, satellite remote sensing, and multi-scale modeling in the Arctic context.

Published

2020

32. The impact of atmospheric oxidation on hygroscopicity and cloud droplet activation of inorganic sea spray aerosol

Author

Rosati, Bernadette, Christiansen, Sigurd, Dinesen, Anders, Roldin, Pontus, Massling, Andreas, Nilsson, E. Douglas, and Bilde, Merete

Published

2021

33. Widespread detection of chlorine oxyacids in the Arctic atmosphere

Author

National Natural Science Foundation of China, European Commission, Academy of Finland, University of Helsinki, National Science Foundation (US), Swiss National Science Foundation, Swiss Polar Institute, Ferring Pharmaceuticals, Fundación la Caixa, Ministerio de Ciencia e Innovación (España), Tham, Yee Jun [0000-0001-7924-5841], Sarnela, Nina [0000-0003-1874-3235], Iyer, Siddharth [0000-0001-5989-609X], Li, Qinyi [0000-0002-5146-5831], Angot, Hélène [0000-0003-4673-8249], Beck, Lisa J. [0000-0003-3700-5895], Carmona-García, Javier [0000-0001-5359-7240], Roca-Sanjuán, Daniel [0000-0001-6495-2770], Peräkylä, Otso [0000-0002-2089-0106], He, Xu-Cheng [0000-0002-7416-306X], Archer, Stephen D. [0000-0001-6054-2424], Jacobi, Hans-Werner [0000-0003-2230-3136], Junninen, Heikki [0000-0001-7178-9430], Kulmala, Markku [0000-0003-3464-7825], Mahajan, Anoop S. [0000-0002-2909-5432], Massling, Andreas [0000-0001-8046-2798], Skov, Henrik [0000-0003-1167-8696], Francisco, Joseph S. [0000-0002-5461-1486], Schmale, Julia [0000-0002-1048-7962], Jokinen, Tuija [0000-0002-1280-1396], Saiz-Lopez, A. [0000-0002-0060-1581], Tham, Yee Jun, Sarnela, Nina, Iyer, Siddharth, Li, Qinyi, Angot, Hélène, Quéléver, Lauriane L. J., Beck, Ivo, Laurila, Tiia, Beck, Lisa J., Boyer, Matthew, Carmona-García, Javier, Borrego-Sánchez, Ana, Roca-Sanjuán, Daniel, Peräkylä, Otso, Thakur, Roseline C., He, Xu-Cheng, Zha, Qiaozhi, Howard, Dean, Blomquist, Byron, Archer, Stephen D., Bariteau, Ludovic, Posman, Kevin, Hueber, Jacques, Helmig, Detlev, Jacobi, Hans-Werner, Junninen, Heikki, Kulmala, Markku, Mahajan, Anoop S., Massling, Andreas, Skov, Henrik, Sipilä, Mikko, Francisco, Joseph S., Schmale, Julia, Jokinen, Tuija, Saiz-Lopez, A., National Natural Science Foundation of China, European Commission, Academy of Finland, University of Helsinki, National Science Foundation (US), Swiss National Science Foundation, Swiss Polar Institute, Ferring Pharmaceuticals, Fundación la Caixa, Ministerio de Ciencia e Innovación (España), Tham, Yee Jun [0000-0001-7924-5841], Sarnela, Nina [0000-0003-1874-3235], Iyer, Siddharth [0000-0001-5989-609X], Li, Qinyi [0000-0002-5146-5831], Angot, Hélène [0000-0003-4673-8249], Beck, Lisa J. [0000-0003-3700-5895], Carmona-García, Javier [0000-0001-5359-7240], Roca-Sanjuán, Daniel [0000-0001-6495-2770], Peräkylä, Otso [0000-0002-2089-0106], He, Xu-Cheng [0000-0002-7416-306X], Archer, Stephen D. [0000-0001-6054-2424], Jacobi, Hans-Werner [0000-0003-2230-3136], Junninen, Heikki [0000-0001-7178-9430], Kulmala, Markku [0000-0003-3464-7825], Mahajan, Anoop S. [0000-0002-2909-5432], Massling, Andreas [0000-0001-8046-2798], Skov, Henrik [0000-0003-1167-8696], Francisco, Joseph S. [0000-0002-5461-1486], Schmale, Julia [0000-0002-1048-7962], Jokinen, Tuija [0000-0002-1280-1396], Saiz-Lopez, A. [0000-0002-0060-1581], Tham, Yee Jun, Sarnela, Nina, Iyer, Siddharth, Li, Qinyi, Angot, Hélène, Quéléver, Lauriane L. J., Beck, Ivo, Laurila, Tiia, Beck, Lisa J., Boyer, Matthew, Carmona-García, Javier, Borrego-Sánchez, Ana, Roca-Sanjuán, Daniel, Peräkylä, Otso, Thakur, Roseline C., He, Xu-Cheng, Zha, Qiaozhi, Howard, Dean, Blomquist, Byron, Archer, Stephen D., Bariteau, Ludovic, Posman, Kevin, Hueber, Jacques, Helmig, Detlev, Jacobi, Hans-Werner, Junninen, Heikki, Kulmala, Markku, Mahajan, Anoop S., Massling, Andreas, Skov, Henrik, Sipilä, Mikko, Francisco, Joseph S., Schmale, Julia, Jokinen, Tuija, and Saiz-Lopez, A.

Abstract

Chlorine radicals are strong atmospheric oxidants known to play an important role in the depletion of surface ozone and the degradation of methane in the Arctic troposphere. Initial oxidation processes of chlorine produce chlorine oxides, and it has been speculated that the final oxidation steps lead to the formation of chloric (HClO3) and perchloric (HClO4) acids, although these two species have not been detected in the atmosphere. Here, we present atmospheric observations of gas-phase HClO3 and HClO4. Significant levels of HClO3 were observed during springtime at Greenland (Villum Research Station), Ny-Ålesund research station and over the central Arctic Ocean, on-board research vessel Polarstern during the Multidisciplinary drifting Observatory for the Study of the Arctic Climate (MOSAiC) campaign, with estimated concentrations up to 7 × 106 molecule cm-3. The increase in HClO3, concomitantly with that in HClO4, was linked to the increase in bromine levels. These observations indicated that bromine chemistry enhances the formation of OClO, which is subsequently oxidized into HClO3 and HClO4 by hydroxyl radicals. HClO3 and HClO4 are not photoactive and therefore their loss through heterogeneous uptake on aerosol and snow surfaces can function as a previously missing atmospheric sink for reactive chlorine, thereby reducing the chlorine-driven oxidation capacity in the Arctic boundary layer. Our study reveals additional chlorine species in the atmosphere, providing further insights into atmospheric chlorine cycling in the polar environment.

Published

2023

34. Concomitant exposure to air pollution, green space and noise, and risk of myocardial infarction: a cohort study from Denmark

Author

Poulsen, Aslak Harbo, primary, Sørensen, Mette, additional, Hvidtfeldt, Ulla A, additional, Ketzel, Matthias, additional, Christensen, Jesper H, additional, Brandt, Jørgen, additional, Frohn, Lise M, additional, Massling, Andreas, additional, Khan, Jibran, additional, Münzel, Thomas, additional, and Raaschou-Nielsen, Ole, additional

Published

2023

35. Short-term exposure to ultrafine particles and children’s hospital admissions in Copenhagen, Denmark

Author

Bergmann, Marie, primary, Andersen, Zorana Jovanovic, additional, Massling, Andreas, additional, Nordstrøm, Claus, additional, Amini, Heresh, additional, Loft, Steffen, additional, So, Rina, additional, Zhang, Jiawei, additional, Hunter, Thomas Cole, additional, and Lim, Youn Hee, additional

Published

2023

36. Impact of 2020 COVID-19 lockdowns on particulate air pollution across Europe

Author

Putaud, Jean-Philippe, primary, Pisoni, Enrico, additional, Mangold, Alexander, additional, Hueglin, Christoph, additional, Sciare, Jean, additional, Pikridas, Michael, additional, Savvides, Chrysanthos, additional, Ondracek, Jakub, additional, Mbengue, Saliou, additional, Wiedensohler, Alfred, additional, Weinhold, Kay, additional, Merkel, Maik, additional, Poulain, Laurent, additional, van Pinxteren, Dominik, additional, Herrmann, Hartmut, additional, Massling, Andreas, additional, Nordstroem, Claus, additional, Alastuey, Andrés, additional, Reche, Cristina, additional, Pérez, Noemí, additional, Castillo, Sonia, additional, Sorribas, Mar, additional, Adame, Jose Antonio, additional, Petaja, Tuukka, additional, Lehtipalo, Katrianne, additional, Niemi, Jarkko, additional, Riffault, Véronique, additional, de Brito, Joel F., additional, Colette, Augustin, additional, Favez, Olivier, additional, Petit, Jean-Eudes, additional, Gros, Valérie, additional, Gini, Maria I., additional, Vratolis, Stergios, additional, Eleftheriadis, Konstantinos, additional, Diapouli, Evangelia, additional, Denier van der Gon, Hugo, additional, Yttri, Karl Espen, additional, and Aas, Wenche, additional

Published

2023

37. The importance of the representation of air pollution emissions for the modeled distribution and radiative effects of black carbon in the Arctic

Author

J. Schacht, B. Heinold, J. Quaas, J. Backman, R. Cherian, A. Ehrlich, A. Herber, W. T. K. Huang, Y. Kondo, A. Massling, P. R. Sinha, B. Weinzierl, M. Zanatta, and I. Tegen

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Aerosol particles can contribute to the Arctic amplification (AA) by direct and indirect radiative effects. Specifically, black carbon (BC) in the atmosphere, and when deposited on snow and sea ice, has a positive warming effect on the top-of-atmosphere (TOA) radiation balance during the polar day. Current climate models, however, are still struggling to reproduce Arctic aerosol conditions. We present an evaluation study with the global aerosol-climate model ECHAM6.3-HAM2.3 to examine emission-related uncertainties in the BC distribution and the direct radiative effect of BC. The model results are comprehensively compared against the latest ground and airborne aerosol observations for the period 2005–2017, with a focus on BC. Four different setups of air pollution emissions are tested. The simulations in general match well with the observed amount and temporal variability in near-surface BC in the Arctic. Using actual daily instead of fixed biomass burning emissions is crucial for reproducing individual pollution events but has only a small influence on the seasonal cycle of BC. Compared with commonly used fixed anthropogenic emissions for the year 2000, an up-to-date inventory with transient air pollution emissions results in up to a 30 % higher annual BC burden locally. This causes a higher annual mean all-sky net direct radiative effect of BC of over 0.1 W m−2 at the top of the atmosphere over the Arctic region (60–90∘ N), being locally more than 0.2 W m−2 over the eastern Arctic Ocean. We estimate BC in the Arctic as leading to an annual net gain of 0.5 W m−2 averaged over the Arctic region but to a local gain of up to 0.8 W m−2 by the direct radiative effect of atmospheric BC plus the effect by the BC-in-snow albedo reduction. Long-range transport is identified as one of the main sources of uncertainties for ECHAM6.3-HAM2.3, leading to an overestimation of BC in atmospheric layers above 500 hPa, especially in summer. This is related to a misrepresentation in wet removal in one identified case at least, which was observed during the ARCTAS (Arctic Research of the Composition of the Troposphere from Aircraft and Satellites) summer aircraft campaign. Overall, the current model version has significantly improved since previous intercomparison studies and now performs better than the multi-model average in the Aerosol Comparisons between Observation and Models (AEROCOM) initiative in terms of the spatial and temporal distribution of Arctic BC.

Published

2019

38. Biogenic and anthropogenic sources of aerosols at the High Arctic site Villum Research Station

Author

I. E. Nielsen, H. Skov, A. Massling, A. C. Eriksson, M. Dall'Osto, H. Junninen, N. Sarnela, R. Lange, S. Collier, Q. Zhang, C. D. Cappa, and J. K. Nøjgaard

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

There are limited measurements of the chemical composition, abundance and sources of atmospheric particles in the High Arctic To address this, we report 93 d of soot particle aerosol mass spectrometer (SP-AMS) data collected from 20 February to 23 May 2015 at Villum Research Station (VRS) in northern Greenland (81∘36′ N). During this period, we observed the Arctic haze phenomenon with elevated PM1 concentrations ranging from an average of 2.3, 2.3 and 3.3 µg m−3 in February, March and April, respectively, to 1.2 µg m−3 in May. Particulate sulfate (SO42-) accounted for 66 % of the non-refractory PM1 with the highest concentration until the end of April and decreasing in May. The second most abundant species was organic aerosol (OA) (24 %). Both OA and PM1, estimated from the sum of all collected species, showed a marked decrease throughout May in accordance with the polar front moving north, together with changes in aerosol removal processes. The highest refractory black carbon (rBC) concentrations were found in the first month of the campaign, averaging 0.2 µg m−3. In March and April, rBC averaged 0.1 µg m−3 while decreasing to 0.02 µg m−3 in May. Positive matrix factorization (PMF) of the OA mass spectra yielded three factors: (1) a hydrocarbon-like organic aerosol (HOA) factor, which was dominated by primary aerosols and accounted for 12 % of OA mass, (2) an Arctic haze organic aerosol (AOA) factor and (3) a more oxygenated marine organic aerosol (MOA) factor. AOA dominated until mid-April (64 %–81 % of OA), while being nearly absent from the end of May and correlated significantly with SO42-, suggesting the main part of that factor is secondary OA. The MOA emerged late at the end of March, where it increased with solar radiation and reduced sea ice extent and dominated OA for the rest of the campaign until the end of May (24 %–74 % of OA), while AOA was nearly absent. The highest O∕C ratio (0.95) and S∕C ratio (0.011) was found for MOA. Our data support the current understanding that Arctic aerosols are highly influenced by secondary aerosol formation and receives an important contribution from marine emissions during Arctic spring in remote High Arctic areas. In view of a changing Arctic climate with changing sea-ice extent, biogenic processes and corresponding source strengths, highly time-resolved data are needed in order to elucidate the components dominating aerosol concentrations and enhance the understanding of the processes taking place.

Published

2019

39. Simultaneous measurements of aerosol size distributions at three sites in the European high Arctic

Author

M. Dall'Osto, D. C. S. Beddows, P. Tunved, R. M. Harrison, A. Lupi, V. Vitale, S. Becagli, R. Traversi, K.-T. Park, Y. J. Yoon, A. Massling, H. Skov, R. Lange, J. Strom, and R. Krejci

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Aerosols are an integral part of the Arctic climate system due to their direct interaction with radiation and indirect interaction through cloud formation. Understanding aerosol size distributions and their dynamics is crucial for the ability to predict these climate relevant effects. When of favourable size and composition, both long-range-transported – and locally formed particles – may serve as cloud condensation nuclei (CCN). Small changes of composition or size may have a large impact on the low CCN concentrations currently characteristic of the Arctic environment. We present a cluster analysis of particle size distributions (PSDs; size range 8–500 nm) simultaneously collected from three high Arctic sites during a 3-year period (2013–2015). Two sites are located in the Svalbard archipelago: Zeppelin research station (ZEP; 474 m above ground) and the nearby Gruvebadet Observatory (GRU; about 2 km distance from Zeppelin, 67 m above ground). The third site (Villum Research Station at Station Nord, VRS; 30 m above ground) is 600 km west-northwest of Zeppelin, at the tip of north-eastern Greenland. The GRU site is included in an inter-site comparison for the first time. K-means cluster analysis provided eight specific aerosol categories, further combined into broad PSD classes with similar characteristics, namely pristine low concentrations (12 %–14 % occurrence), new particle formation (16 %–32 %), Aitken (21 %–35 %) and accumulation (20 %–50 %). Confined for longer time periods by consolidated pack sea ice regions, the Greenland site GRU shows PSDs with lower ultrafine-mode aerosol concentrations during summer but higher accumulation-mode aerosol concentrations during winter, relative to the Svalbard sites. By association with chemical composition and cloud condensation nuclei properties, further conclusions can be derived. Three distinct types of accumulation-mode aerosol are observed during winter months. These are associated with sea spray (largest detectable sizes, >400 nm), Arctic haze (main mode at 150 nm) and aged accumulation-mode (main mode at 220 nm) aerosols. In contrast, locally produced particles, most likely of marine biogenic origin, exhibit size distributions dominated by the nucleation and Aitken mode during summer months. The obtained data and analysis point towards future studies, including apportioning the relative contribution of primary and secondary aerosol formation processes and elucidating anthropogenic aerosol dynamics and transport and removal processes across the Greenland Sea. In order to address important research questions in the Arctic on scales beyond a singular station or measurement events, it is imperative to continue strengthening international scientific cooperation.

Published

2019

40. Interactions between the atmosphere, cryosphere, and ecosystems at northern high latitudes

Author

M. Boy, E. S. Thomson, J.-C. Acosta Navarro, O. Arnalds, E. Batchvarova, J. Bäck, F. Berninger, M. Bilde, Z. Brasseur, P. Dagsson-Waldhauserova, D. Castarède, M. Dalirian, G. de Leeuw, M. Dragosics, E.-M. Duplissy, J. Duplissy, A. M. L. Ekman, K. Fang, J.-C. Gallet, M. Glasius, S.-E. Gryning, H. Grythe, H.-C. Hansson, M. Hansson, E. Isaksson, T. Iversen, I. Jonsdottir, V. Kasurinen, A. Kirkevåg, A. Korhola, R. Krejci, J. E. Kristjansson, H. K. Lappalainen, A. Lauri, M. Leppäranta, H. Lihavainen, R. Makkonen, A. Massling, O. Meinander, E. D. Nilsson, H. Olafsson, J. B. C. Pettersson, N. L. Prisle, I. Riipinen, P. Roldin, M. Ruppel, M. Salter, M. Sand, Ø. Seland, H. Seppä, H. Skov, J. Soares, A. Stohl, J. Ström, J. Svensson, E. Swietlicki, K. Tabakova, T. Thorsteinsson, A. Virkkula, G. A. Weyhenmeyer, Y. Wu, P. Zieger, and M. Kulmala

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The Nordic Centre of Excellence CRAICC (Cryosphere–Atmosphere Interactions in a Changing Arctic Climate), funded by NordForsk in the years 2011–2016, is the largest joint Nordic research and innovation initiative to date, aiming to strengthen research and innovation regarding climate change issues in the Nordic region. CRAICC gathered more than 100 scientists from all Nordic countries in a virtual centre with the objectives of identifying and quantifying the major processes controlling Arctic warming and related feedback mechanisms, outlining strategies to mitigate Arctic warming, and developing Nordic Earth system modelling with a focus on short-lived climate forcers (SLCFs), including natural and anthropogenic aerosols. The outcome of CRAICC is reflected in more than 150 peer-reviewed scientific publications, most of which are in the CRAICC special issue of the journal Atmospheric Chemistry and Physics. This paper presents an overview of the main scientific topics investigated in the centre and provides the reader with a state-of-the-art comprehensive summary of what has been achieved in CRAICC with links to the particular publications for further detail. Faced with a vast amount of scientific discovery, we do not claim to completely summarize the results from CRAICC within this paper, but rather concentrate here on the main results which are related to feedback loops in climate change–cryosphere interactions that affect Arctic amplification.

Published

2019

41. Abiotic and biotic sources influencing spring new particle formation in North East Greenland

Author

Dall´Osto, M., Simo, R., Harrison, Roy M., Beddows, D.C.S., Saiz-Lopez, A., Lange, R., Skov, H., Nøjgaard, J.K., Nielsen, I.E., and Massling, A.

Published

2018

42. Characterization of distinct Arctic aerosol accumulation modes and their sources

Author

Lange, R., Dall’Osto, M., Skov, H., Nøjgaard, J.K., Nielsen, I.E., Beddows, D.C.S., Simo, R., Harrison, R.M., and Massling, A.

Published

2018

43. Elucidating the present-day chemical composition, seasonality and source regions of climate-relevant aerosols across the Arctic land surface

Author

Vaios Moschos, Julia Schmale, Wenche Aas, Silvia Becagli, Giulia Calzolai, Konstantinos Eleftheriadis, Claire E Moffett, Jürgen Schnelle-Kreis, Mirko Severi, Sangeeta Sharma, Henrik Skov, Mika Vestenius, Wendy Zhang, Hannele Hakola, Heidi Hellén, Lin Huang, Jean-Luc Jaffrezo, Andreas Massling, Jakob K Nøjgaard, Tuukka Petäjä, Olga Popovicheva, Rebecca J Sheesley, Rita Traversi, Karl Espen Yttri, André S H Prévôt, Urs Baltensperger, and Imad El Haddad

Subjects

Arctic, natural aerosol, anthropogenic aerosol, chemical composition, long-range air mass transport, aerosol-climate effects, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

The Arctic is warming two to three times faster than the global average, and the role of aerosols is not well constrained. Aerosol number concentrations can be very low in remote environments, rendering local cloud radiative properties highly sensitive to available aerosol. The composition and sources of the climate-relevant aerosols, affecting Arctic cloud formation and altering their microphysics, remain largely elusive due to a lack of harmonized concurrent multi-component, multi-site, and multi-season observations. Here, we present a dataset on the overall chemical composition and seasonal variability of the Arctic total particulate matter (with a size cut at 10 μ m, PM _10 , or without any size cut) at eight observatories representing all Arctic sectors. Our holistic observational approach includes the Russian Arctic, a significant emission source area with less dedicated aerosol monitoring, and extends beyond the more traditionally studied summer period and black carbon/sulfate or fine-mode pollutants. The major airborne Arctic PM components in terms of dry mass are sea salt, secondary (non-sea-salt, nss) sulfate, and organic aerosol (OA), with minor contributions from elemental carbon (EC) and ammonium. We observe substantial spatiotemporal variability in component ratios, such as EC/OA, ammonium/nss-sulfate and OA/nss-sulfate, and fractional contributions to PM. When combined with component-specific back-trajectory analysis to identify marine or terrestrial origins, as well as the companion study by Moschos et al 2022 Nat. Geosci. focusing on OA, the composition analysis provides policy-guiding observational insights into sector-based differences in natural and anthropogenic Arctic aerosol sources. In this regard, we first reveal major source regions of inner-Arctic sea salt, biogenic sulfate, and natural organics, and highlight an underappreciated wintertime source of primary carbonaceous aerosols (EC and OA) in West Siberia, potentially associated with the oil and gas sector. The presented dataset can assist in reducing uncertainties in modelling pan-Arctic aerosol-climate interactions, as the major contributors to yearly aerosol mass can be constrained. These models can then be used to predict the future evolution of individual inner-Arctic atmospheric PM components in light of current and emerging pollution mitigation measures and improved region-specific emission inventories.

Published

2022

44. Association Between Short-term Exposure to Ultrafine Particles and Mortality in Eight European Urban Areas

Author

UF&HEALTH Study Group, Stafoggia, Massimo, Schneider, Alexandra, Cyrys, Josef, Samoli, Evangelia, Andersen, Zorana Jovanovic, Bedada, Getahun Bero, Bellander, Tom, Cattani, Giorgio, Eleftheriadis, Konstantinos, Faustini, Annunziata, Hoffmann, Barbara, Jacquemin, Bénédicte, Katsouyanni, Klea, Massling, Andreas, Pekkanen, Juha, Perez, Noemi, Peters, Annette, Quass, Ulrich, Yli-Tuomi, Tarja, and Forastiere, Francesco

Published

2017

45. Modelling wintertime sea-spray aerosols under Arctic haze conditions

Author

Ioannidis, Eleftherios, primary, Law, Kathy S., additional, Raut, Jean-Christophe, additional, Marelle, Louis, additional, Onishi, Tatsuo, additional, Kirpes, Rachel M., additional, Upchurch, Lucia M., additional, Tuch, Thomas, additional, Wiedensohler, Alfred, additional, Massling, Andreas, additional, Skov, Henrik, additional, Quinn, Patricia K., additional, and Pratt, Kerri A., additional

Published

2023

46. Learning from the temperature sensitivity of biogenic and Arctic ice nucleating particles

Author

Wex, Heike, primary, Gundlach, Josephine, additional, Backes, Anna Theresa, additional, Fröhlich-Nowoisky, Janine, additional, Sze, Kevin Cheuk Hang, additional, Massling, Andi, additional, Skov, Henrik, additional, Schnell, Russell, additional, and Hartmann, Susan, additional

Published

2023

47. Atmospheric Pollution Research on Greenland

Author

Skov, Henrik, Bossi, Rossana, Massling, Andreas, Sørensen, Lise-Lotte, Nøjgaard, Jacob Klenø, Christensen, Jesper, Hansen, Kaj Mantzius, Jensen, Bjarne, Glasius, Marianne, Kallenborn, Roland, Series editor, di Prisco, Guido, Series editor, Walton, David, Series editor, and Barr, Susan, Series editor

Published

2016

48. Concomitant exposure to air pollution, green space and noise, and risk of myocardial infarction: a cohort study from Denmark.

Author

Poulsen, Aslak Harbo, Sørensen, Mette, Hvidtfeldt, Ulla A, Ketzel, Matthias, Christensen, Jesper H, Brandt, Jørgen, Frohn, Lise M, Massling, Andreas, Khan, Jibran, Münzel, Thomas, and Raaschou-Nielsen, Ole

Published

2024

49. Morphology and hygroscopicity of nanoplastics in sea spray.

Author

Petters, Sarah Suda, Kjærgaard, Eva Rosendal, Hasager, Freja, Massling, Andreas, Glasius, Marianne, and Bilde, Merete

Abstract

The role of airborne nanoparticles in atmospheric chemistry and public health is largely controlled by particle size, morphology, surface composition, and coating. Aerosol mass spectrometry provides real-time chemical characterization of submicron atmospheric particles, but analysis of nanoplastics in complex aerosol mixtures such as sea spray is severely limited by challenges associated with separation and ionization of the aerosol matrix. Here we characterize the internal and external mixing state of synthetic sea spray aerosols spiked with 150 nm nanoplastics. Aerosols generated from pneumatic atomization and from a sea spray tank are compared. A humidified tandem differential mobility analyzer is used as a size and hygroscopicity filter, resulting in separation of nanoplastics from sea spray, and an inline high-resolution time-of-flight aerosol mass spectrometer is used to characterize particle composition and ionization efficiency. The separation technique amplified the detection limit of the airborne nanoplastics. A salt coating was found on the nanoplastics with coating thickness increasing exponentially with increasing bulk solution salinity, which was varied from 0 to 40 g kg−1. Relative ionization efficiencies of polystyrene and sea salt chloride were 0.19 and 0.36, respectively. The growth-factor derived hygroscopicity of sea salt was 1.4 at 75% relative humidity. These results underscore the importance of separating airborne nanoplastics from sea salt aerosol for detailed online characterization by aerosol mass spectrometry and characterization of salt coatings as a function of water composition. The surface coating of nanoplastic aerosols by salts can profoundly impact their surface chemistry, water uptake, and humidified particle size distributions in the atmosphere. [ABSTRACT FROM AUTHOR]

Published

2023

50. The Particle Project 2022

Author

Ellermann, Thomas, Massling, Andreas, Poulsen, Maria Bech, and Nordstrøm, Claus

Published

2023