Your search keyword '"FORMATION EVENTS"' showing total 4 results

1. Observed coupling between air mass history, secondary growth of nucleation mode particles and aerosol pollution levels in Beijing

Author

S. Hakala, V. Vakkari, F. Bianchi, L. Dada, C. Deng, K. R. Dällenbach, Y. Fu, J. Jiang, J. Kangasluoma, J. Kujansuu, Y. Liu, T. Petäjä, L. Wang, C. Yan, M. Kulmala, P. Paasonen, Air quality research group, Institute for Atmospheric and Earth System Research (INAR), and Polar and arctic atmospheric research (PANDA)

Subjects

CHINA ANTHROPOGENIC EMISSIONS, SIZE DISTRIBUTIONS, LONG-TERM, FORMATION EVENTS, PM2.5 TRENDS, HAZE POLLUTION, 114 Physical sciences, Pollution, Analytical Chemistry, NUMBER, SULFURIC-ACID, Chemistry (miscellaneous), Environmental Chemistry, FINE PARTICULATE MATTER, ORGANIC-COMPOUNDS

Abstract

Atmospheric aerosols have significant effects on the climate and on human health. New particle formation (NPF) is globally an important source of aerosols but its relevance especially towards aerosol mass loadings in highly polluted regions is still controversial. In addition, uncertainties remain regarding the processes leading to severe pollution episodes, concerning e.g. the role of atmospheric transport. In this study, we utilize air mass history analysis in combination with different fields related to the intensity of anthropogenic emissions in order to calculate air mass exposure to anthropogenic emissions (AME) prior to their arrival at Beijing, China. The AME is used as a semi-quantitative metric for describing the effect of air mass history on the potential for aerosol formation. We show that NPF events occur in clean air masses, described by low AME. However, increasing AME seems to be required for substantial growth of nucleation mode (diameter < 30 nm) particles, originating either from NPF or direct emissions, into larger mass-relevant sizes. This finding assists in establishing and understanding the connection between small nucleation mode particles, secondary aerosol formation and the development of pollution episodes. We further use the AME, in combination with basic meteorological variables, for developing a simple and easy-to-apply regression model to predict aerosol volume and mass concentrations. Since the model directly only accounts for changes in meteorological conditions, it can also be used to estimate the influence of emission changes on pollution levels. We apply the developed model to briefly investigate the effects of the COVID-19 lockdown on PM2.5 concentrations in Beijing. While no clear influence directly attributable to the lockdown measures is found, the results are in line with other studies utilizing more widely applied approaches.

Published

2022

2. Investigation of new particle formation mechanisms and aerosol processes at Marambio Station, Antarctic Peninsula

Author

Lauriane L. J. Quéléver, Lubna Dada, Eija Asmi, Janne Lampilahti, Tommy Chan, Jonathan E. Ferrara, Gustavo E. Copes, German Pérez-Fogwill, Luis Barreira, Minna Aurela, Douglas R. Worsnop, Tuija Jokinen, Mikko Sipilä, Institute for Atmospheric and Earth System Research (INAR), Polar and arctic atmospheric research (PANDA), and Air quality research group

Subjects

formation events, Atmospheric Science, nucleation mode particles, molecular clusters, sea-ice, sulfuric-acid, growth, size distribution, ion, iodine emissions, neutral cluster, 114 Physical sciences

Abstract

Understanding chemical processes leading to the formation of atmospheric aerosol particles is crucial to improve our capabilities in predicting the future climate. However, those mechanisms are still inadequately characterized, especially in polar regions. In this study, we report observations of neutral and charged aerosol precursor molecules and chemical cluster composition (qualitatively and quantitatively), as well as air ions and aerosol particle number concentrations and size distributions from the Marambio research station (64∘15′ S, 56∘38′ W), located north of the Antarctic Peninsula. We conducted measurements during the austral summer, between 15 January and 25 February 2018. The scope of this study is to characterize new particle formation (NPF) event parameters and connect our observations of gas-phase compounds with the formation of secondary aerosols to resolve the nucleation mechanisms at the molecular scale. NPF occurred on 40 % of measurement days. All NPF events were observed during days with high solar radiation, mostly with above-freezing temperatures and with low relative humidity. The averaged formation rate for 3 nm particles (J3) was 0.686 cm−3 s−1, and the average particle growth rate (GR3.8–12 nm) was 4.2 nm h−1. Analysis of neutral aerosol precursor molecules showed measurable concentrations of iodic acid (IA), sulfuric acid (SA), and methane sulfonic acid (MSA) throughout the entire measurement period with significant increase in MSA and SA concentrations during NPF events. We highlight SA as a key contributor to NPF processes, while IA and MSA likely only contribute to particle growth. Mechanistically, anion clusters containing ammonia and/or dimethylamine (DMA) and SA were identified, suggesting significant concentration of ammonia and DMA as well. Those species are likely contributing to NPF events since SA alone is not sufficient to explain observed nucleation rates. Here, we provide evidence of the marine origin of the measured chemical precursors and discuss their potential contribution to the aerosol phase.

Published

2022

3. Quiet New Particle Formation in the Atmosphere

Author

Markku Kulmala, Heikki Junninen, Lubna Dada, Imre Salma, Tamás Weidinger, Wanda Thén, Máté Vörösmarty, Kaupo Komsaare, Dominik Stolzenburg, Runlong Cai, Chao Yan, Xinyang Li, Chenjuan Deng, Jingkun Jiang, Tuukka Petäjä, Tuomo Nieminen, Veli-Matti Kerminen, Institute for Atmospheric and Earth System Research (INAR), Air quality research group, and Global Atmosphere-Earth surface feedbacks

Subjects

1171 Geosciences, GROWTH-RATES, FORMATION EVENTS, AIR, aerosol production, BOUNDARY-LAYER, NPF EVENTS, 114 Physical sciences, SMEAR-II, GLOBAL ANALYSIS, instrument sensitivity, AEROSOL-PARTICLES, long-term observations, SIZE DISTRIBUTION DATA, classification of NPF events, 1172 Environmental sciences, clustering, NUCLEATION, General Environmental Science

Abstract

Atmospheric new particle formation (NPF) has been observed to take place in practice all around the world. In continental locations, typically about 10–40% of the days are so-called NPF event days characterized by a clear particle formation and growth that continue for several hours, occurring mostly during daytime. The other days are either non-event days, or days for which it is difficult to decide whether NPF had occurred or not. Using measurement data from several locations (Hyytiälä, Järvselja, and near-city background and city center of Budapest), we were able to show that NPF tends to occur also on the days traditionally characterized as non-event days. One explanation is the instrument sensitivity towards low number concentrations in the sub-10 nm range, which usually limits our capability to detect such NPF events. We found that during such days, particle formation rates at 6 nm were about 2–20% of those observed during the traditional NPF event days. Growth rates of the newly formed particles were very similar between the traditional NPF event and non-event days. This previously overlooked phenomenon, termed as quiet NPF, contributes significantly to the production of secondary particles in the atmosphere.

Published

2022

4. Measurement report: New particle formation characteristics at an urban and a mountain station in northern China

Author

Y. Zhou, S. Hakala, C. Yan, Y. Gao, X. Yao, B. Chu, T. Chan, J. Kangasluoma, S. Gani, J. Kontkanen, P. Paasonen, Y. Liu, T. Petäjä, M. Kulmala, L. Dada, Institute for Atmospheric and Earth System Research (INAR), and Air quality research group

Subjects

formation events, Atmospheric Science, 010504 meteorology & atmospheric sciences, QC1-999, Particle (ecology), 010501 environmental sciences, growth-rates, Atmospheric sciences, 01 natural sciences, 114 Physical sciences, sulfuric-acid, nucleation-mode, n-ccn, 11. Sustainability, aerosol-size distribution, Cloud condensation nuclei, QD1-999, Air quality index, Air mass, 0105 earth and related environmental sciences, long-term, fast-mobility, Physics, Aerosol, cloud condensation nuclei, Chemistry, 13. Climate action, Particle growth, Environmental science, Spatial variability, Sink (computing), yangtze-river delta

Abstract

Atmospheric new particle formation (NPF) events have attracted increasing attention for their contribution to the global aerosol number budget and therefore their effects on climate, air quality and human health. NPF events are regarded as a regional phenomenon, occurring over a large area. Most observations of NPF events in Beijing and its vicinity were conducted in populated areas, whereas observations of NPF events on mountaintops with low anthropogenic emissions are still rare in China. The spatial variation of NPF event intensity has not been investigated in detail by incorporating both urban areas and mountain measurements in Beijing. Here, we provide NPF event characteristics in summer 2018 and 2019 at urban Beijing and a comparison of NPF event characteristics – NPF event frequency, formation rate and growth rate – by comparing an urban Beijing site and a background mountain site separated by ∼80 km from 14 June to 14 July 2019, as well as giving insights into the connection between both locations. During parallel measurements at urban Beijing and mountain background areas, although the median condensation sink during the first 2 h of the common NPF events was around 0.01 s−1 at both sites, there were notable differences in formation rates between the two locations (median of 5.42 cm−3 s−1 at the urban site and 1.13 cm−3 s−1 at the mountain site during the first 2 h of common NPF events). In addition, the growth rates in the 7–15 nm range for common NPF events at the urban site (median of 7.6 nm h−1) were slightly higher than those at the mountain site (median of 6.5 nm h−1). To understand whether the observed events were connected, we compared air mass trajectories as well as meteorological conditions at both stations. Favorable conditions for the occurrence of regional NPF events were largely affected by air mass transport. Overall, our results demonstrate a clear inhomogeneity of regional NPF within a distance of ∼100 km, possibly due to the discretely distributed emission sources.

Published

2021