2016, Tröstl, Jasmin, Herrmann, Erik, Frege, Carla, Bianchi, Federico, Molteni, Ugo, Bukowiecki, Nicolas, Hoyle, Christopher R., Steinbacher, Martin, Weingartner, Ernest, Dommen, Josef, Gysel, Martin, Baltensperger, Urs

Previous modeling studies hypothesized that a large fraction of cloud condensation nuclei (CCN) is attributed to new particle formation (NPF) in the free troposphere. Despite the potential importance of this process, only few long‐term observations have been performed to date. Here we present the results of a 12 month campaign of NPF observations at the high‐altitude site Jungfraujoch (JFJ, 3580 m above sea level (asl)). Our results show that NPF significantly adds to the total aerosol concentration at the JFJ and only occurs via previous precursor entrainment from the planetary boundary layer (PBL). Freshly nucleated particles do not directly grow to CCN size (90 nm) within observable time scales (maximum 48 h). The contribution of NPF to the CCN concentration is low within this time frame compared to other sources, such as PBL entrainment of larger particles. A multistep growth mechanism is proposed which allows previously formed Aitken mode particles to add to the CCN concentration. A parametrization is derived to explain formation rates at the JFJ, showing that precursor concentration, PBL influence, and global radiation are the key factors controlling new particle formation at the site.

2016, Gordon, Hamish, Sengupta, Kamalika, Rap, Alexandru, Duplissy, Jonathan, Frege, Carla, Williamson, Christina, Heinritzi, Martin, Simon, Mario, Yan, Chao, Almeida, João, Tröstl, Jasmin, Nieminen, Tuomo, Ortega, Ismael K., Wagner, Robert, Dunne, Eimear M., Adamov, Alexey, Amorim, Antonio, Bernhammer, Anne-Kathrin, Bianchi, Federico, Breitenlechner, Martin, Brilke, Sophia, Chen, Xuemeng, Craven, Jill S., Dias, Antonio, Ehrhart, Sebastian, Fischer, Lukas, Flagan, Richard C., Franchin, Alessandro, Fuchs, Claudia, Guida, Roberto, Hakala, Jani, Hoyle, Christopher R., Jokinen, Tuija, Junninen, Heikki, Kangasluoma, Juha, Kim, Jaeseok, Kirkby, Jasper, Krapf, Manuel, Kürten, Andreas, Laaksonen, Ari, Lehtipalo, Katrianne, Makhmutov, Vladimir, Mathot, Serge, Molteni, Ugo, Monks, Sarah A., Onnela, Antti, Peräkylä, Otso, Piel, Felix, Petäjä, Tuukka, Praplan, Arnaud P., Pringle, Kirsty J., Richards, Nigel A. D., Rissanen, Matti P., Rondo, Linda, Sarnela, Nina, Schobesberger, Siegfried, Scott, Catherine E., Seinfeld, John H., Sharma, Sangeeta, Sipilä, Mikko, Steiner, Gerhard, Stozhkov, Yuri, Stratmann, Frank, Tomé, Antonio, Virtanen, Annele, Vogel, Alexander Lucas, Wagner, Andrea C., Wagner, Paul E., Weingartner, Ernest, Wimmer, Daniela, Winkler, Paul M., Ye, Penglin, Zhang, Xuan, Hansel, Armin, Dommen, Josef, Donahue, Neil M., Worsnop, Douglas R., Baltensperger, Urs, Kulmala, Markku, Curtius, Joachim, Carslaw, Kenneth S.

A mechanism for the formation of atmospheric aerosols via the gas to particle conversion of highly oxidized organic molecules is found to be the dominant aerosol formation process in the preindustrial boundary layer over land. The inclusion of this process in a global aerosol model raises baseline preindustrial aerosol concentrations and could lead to a reduction of 27% in estimates of anthropogenic aerosol radiative forcing.

2013-05-24, Bianchi, Federico, Junninen, Heikki, Tröstl, Jasmin, Duplissy, Jonathan, Rondo, Linda, Simon, Mario, Kürten, Andreas, Adamov, Alexey, Curtius, Joachim, Dommen, Josef, Weingartner, Ernest, Worsnop, Douglas R., Kulmala, Markku, Baltensperger, Urs, DeMott, Paul J., O´Dowd Colin D.

2013, Mertes, Peter, Praplan, Arnaud P., Künzi, Lisa, Dommen, Josef, Baltensperger, Urs, Geiser, Marianne, Weingartner, Ernest, Ricka, Jaroslav, Fierz, Martin, Kalberer, Markus

2016, Bianchi, Federico, Tröstl, Jasmin, Junninen, Heikki, Frege, Carla, Henne, Stephan, Hoyle, Christopher R., Molteni, Ugo, Herrmann, Erik, Adamov, Alexey, Bukowiecki, Nicolas, Chen, Xuemeng, Duplissy, Jonathan, Gysel, Martin, Hutterli, Manuel, Kangasluoma, Juha, Kontkanen, Jenni, Kürten, Andreas, Manninen, Hanna E., Münch, Steffen, Peräkylä, Otso, Petäjä, Tuukka, Rondo, Linda, Williamson, Christina, Weingartner, Ernest, Curtius, Joachim, Worsnop, Douglas R., Kulmala, Markku, Dommen, Josef, Baltensperger, Urs

From neutral to new Many of the particles in the troposphere are formed in situ, but what fraction of all tropospheric particles do they constitute and how exactly are they made? Bianchi et al report results from a high-altitude research station. Roughly half of the particles were newly formed by the condensation of highly oxygenated multifunctional compounds. A combination of laboratory results, field measurements, and model calculations revealed that neutral nucleation is more than 10 times faster than ion-induced nucleation, that particle growth rates are size-dependent, and that new particle formation occurs during a limited time window.

2014, Riccobono, Francesco, Schobesberger, Siegfried, Scott, Catherine E., Dommen, Josef, Ortega, Ismael K., Rondo, Linda, Almeida, João, Amorim, Antonio, Bianchi, Federico, Breitenlechner, Martin, David, André, Downard, Andrew, Dunne, Eimear M., Duplissy, Jonathan, Ehrhart, Sebastian, Flagan, Richard C., Franchin, Alessandro, Hansel, Armin, Junninen, Heikki, Kajos, Maija, Keskinen, Helmi, Kupc, Agnieszka, Kürten, Andreas, Kvashin, Alexander N., Laaksonen, Ari, Lehtipalo, Katrianne, Makhmutov, Vladimir, Mathot, Serge, Nieminen, Tuomo, Onnela, Antti, Petäjä, Tuukka, Praplan, Arnaud P., Santos, Filipe D., Schallhart, Simon, Seinfeld, John H., Sipilä, Mikko, Spracklen, Dominick V., Stozhkov, Yuri, Stratmann, Frank, Tomé, Antonio, Tsagkogeorgas, Georgios, Vaattovaara, Petri, Viisanen, Yrjö, Vrtala, Aron, Wagner, Paul E., Weingartner, Ernest, Wex, Heike, Wimmer, Daniela, Carslaw, Kenneth S., Curtius, Joachim, Donahue, Neil M., Kirkby, Jasper, Kulmala, Markku, Worsnop, Douglas R., Baltensperger, Urs

Out of the Air New-particle formation from gaseous precursors in the atmosphere is a complex and poorly understood process with importance in atmospheric chemistry and climate. Laboratory studies have had trouble reproducing the particle formation rates that must occur in the natural world. Riccobono et al. used the CLOUD (Cosmics Leaving Outdoor Droplets) chamber at CERN to recreate a realistic atmospheric environment. Sulfuric acid and oxidized organic vapors in typical natural concentrations caused particle nucleation at similar rates to those observed in the lower atmosphere.

2013, Keskinen, Helmi, Virtanen, Annele, Joutsensaari, Jorma, Tsagkogeorgas, Georgios, Duplissy, Jonathan, Schobesberger, Siegfried, Gysel, Martin, Riccobono, Francesco, Slowik, Jay Gates, Bianchi, Federico, Yli-Juuti, Taina, Lehtipalo, Katrianne, Rondo, Linda, Breitenlechner, Martin, Kupc, Agnieszka, Almeida, João, Amorim, Antonio, Dunne, Eimear M., Downard, Andrew J., Ehrhart, Sebastian, Franchin, Alessandro, Kajos, Maija K., Kirkby, Jasper, Kürten, Andreas, Nieminen, Tuomo, Makhmutov, Vladimir, Mathot, Serge, Miettinen, Pasi, Onnela, Antti, Petäjä, Tuukka, Praplan, Arnaud, Santos, Felipe D., Schallhart, Simon, Sipilä, Mikko, Stozhkov, Yuri, Tomé, Antonio, Vaattovaara, Petri, Wimmer, Daniela, Prévôt, André, Dommen, Josef, Donahue, Neil M., Flagan, Richard C., Weingartner, Ernest, Viisanen, Yrjö, Riipinen, Ilona, Hansel, Armin, Curtius, Joachim, Kulmala, Markku, Worsnop, Douglas R., Baltensperger, Urs, Wex, Heike, Stratmann, Frank, Laaksonen, Ari

Sulphuric acid, ammonia, amines, and oxidised organics play a crucial role in nanoparticle formation in the atmosphere. In this study, we investigate the composition of nucleated nanoparticles formed from these compounds in the CLOUD (Cosmics Leaving Outdoor Droplets) chamber experiments at CERN (Centre européen pour la recherche nucléaire). The investigation was carried out via analysis of the particle hygroscopicity, ethanol affinity, oxidation state, and ion composition. Hygroscopicity was studied by a hygroscopic tandem differential mobility analyser and a cloud condensation nuclei counter, ethanol affinity by an organic differential mobility analyser and particle oxidation level by a high-resolution time-of-flight aerosol mass spectrometer. The ion composition was studied by an atmospheric pressure interface time-of-flight mass spectrometer. The volume fraction of the organics in the particles during their growth from sizes of a few nanometers to tens of nanometers was derived from measured hygroscopicity assuming the Zdanovskii–Stokes–Robinson relationship, and compared to values gained from the spectrometers. The ZSR-relationship was also applied to obtain the measured ethanol affinities during the particle growth, which were used to derive the volume fractions of sulphuric acid and the other inorganics (e.g. ammonium salts). In the presence of sulphuric acid and ammonia, particles with a mobility diameter of 150 nm were chemically neutralised to ammonium sulphate. In the presence of oxidation products of pinanediol, the organic volume fraction of freshly nucleated particles increased from 0.4 to ~0.9, with an increase in diameter from 2 to 63 nm. Conversely, the sulphuric acid volume fraction decreased from 0.6 to 0.1 when the particle diameter increased from 2 to 50 nm. The results provide information on the composition of nucleated aerosol particles during their growth in the presence of various combinations of sulphuric acid, ammonia, dimethylamine and organic oxidation products.

2016, Tröstl, Jasmin, Chuang, Wayne K., Gordon, Hamish, Heinritzi, Martin, Yan, Chao, Molteni, Ugo, Ahlm, Lars, Frege, Carla, Bianchi, Federico, Wagner, Robert, Simon, Mario, Lehtipalo, Katrianne, Williamson, Christina, Craven, Jill S., Duplissy, Jonathan, Adamov, Alexey, Almeida, Joao, Bernhammer, Anne-Kathrin, Breitenlechner, Martin, Brilke, Sophia, Dias, Antònio, Ehrhart, Sebastian, Flagan, Richard C., Franchin, Alessandro, Fuchs, Claudia, Guida, Roberto, Gysel, Martin, Hansel, Armin, Hoyle, Christopher R., Jokinen, Tuija, Junninen, Heikki, Kangasluoma, Juha, Keskinen, Helmi, Kim, Jaeseok, Krapf, Manuel, Kürten, Andreas, Laaksonen, Ari, Lawler, Michael, Leiminger, Markus, Mathot, Serge, Möhler, Ottmar, Nieminen, Tuomo, Onnela, Antti, Petäjä, Tuukka, Piel, Felix M., Miettinen, Pasi, Rissanen, Matti P., Rondo, Linda, Sarnela, Nina, Schobesberger, Siegfried, Sengupta, Kamalika, Sipilä, Mikko, Smith, James N., Steiner, Gerhard, Tomè, Antònio, Virtanen, Annele, Wagner, Andrea C., Weingartner, Ernest, Wimmer, Daniela, Winkler, Paul M., Ye, Penglin, Carslaw, Kenneth S., Curtius, Joachim, Dommen, Josef, Kirkby, Jasper, Kulmala, Markku, Riipinen, Ilona, Worsnop, Douglas R., Donahue, Neil M., Baltensperger, Urs

About half of present-day cloud condensation nuclei originate from atmospheric nucleation, frequently appearing as a burst of new particles near midday1. Atmospheric observations show that the growth rate of new particles often accelerates when the diameter of the particles is between one and ten nanometres2,3. In this critical size range, new particles are most likely to be lost by coagulation with pre-existing particles4, thereby failing to form new cloud condensation nuclei that are typically 50 to 100 nanometres across. Sulfuric acid vapour is often involved in nucleation but is too scarce to explain most subsequent growth5,6, leaving organic vapours as the most plausible alternative, at least in the planetary boundary layer7,8,9,10. Although recent studies11,12,13 predict that low-volatility organic vapours contribute during initial growth, direct evidence has been lacking. The accelerating growth may result from increased photolytic production of condensable organic species in the afternoon2, and the presence of a possible Kelvin (curvature) effect, which inhibits organic vapour condensation on the smallest particles (the nano-Köhler theory)2,14, has so far remained ambiguous. Here we present experiments performed in a large chamber under atmospheric conditions that investigate the role of organic vapours in the initial growth of nucleated organic particles in the absence of inorganic acids and bases such as sulfuric acid or ammonia and amines, respectively. Using data from the same set of experiments, it has been shown15 that organic vapours alone can drive nucleation. We focus on the growth of nucleated particles and find that the organic vapours that drive initial growth have extremely low volatilities (saturation concentration less than 10−4.5 micrograms per cubic metre). As the particles increase in size and the Kelvin barrier falls, subsequent growth is primarily due to more abundant organic vapours of slightly higher volatility (saturation concentrations of 10−4.5 to 10−0.5 micrograms per cubic metre). We present a particle growth model that quantitatively reproduces our measurements. Furthermore, we implement a parameterization of the first steps of growth in a global aerosol model and find that concentrations of atmospheric cloud concentration nuclei can change substantially in response, that is, by up to 50 per cent in comparison with previously assumed growth rate parameterizations.

2013-06-24, Keskinen, Helmi, Virtanen, Annele, Joutsensaari, Jorma, Tsagkogeorgas, Georgios, Duplissy, Jonathan, Schobesberger, Siegfried, Gysel, Martin, Riccobono, Francesco, Slowik, Jay Gates, Bianchi, Federico, Yli-Juuti, Taina, Lehtipalo, Katrianne, Rondo, Linda, Breitenlechner, Martin, Kupc, Agnieszka, Almeida, João, Amorim, Antonio, Dunne, Eimear M., Downard, Andrew J., Ehrhart, Sebastian, Franchin, Alessandro, Kajos, Maija K., Kirkby, Jasper, Kürten, Andreas, Nieminen, Tuomo, Makhmutov, Vladimir, Mathot, Serge, Miettinen, Pasi, Onnela, Antti, Petäjä, Tuukka, Praplan, Arnaud, Santos, Filipe D., Schallhart, Simon, Sipilä, Mikko, Stozhkov, Yuri, Tomé, Antonio, Vaattovaara, Petri, Wimmer, Daniela, Prévôt, André, Dommen, Josef, Donahue, Neil M., Flagan, Richard C., Viisanen, Yrjö, Weingartner, Ernest, Riipinen, Ilona, Hansel, Armin, Curtius, Joachim, Kulmala, Markku, Worsnop, Douglas R., Baltensperger, Urs, Wex, Heike, Stratmann, Frank, Laaksonen, Ari, DeMott, Paul J., O'Dowd, Colin D.

2013, Frosch, Mia, Bilde, Merete, Nenes, Athanasios, Praplan, Arnaud P., Jurányi, Zsófia, Dommen, Josef, Gysel, Martin, Weingartner, Ernest, Baltensperger, Urs

In a series of smog chamber experiments, the cloud condensation nuclei (CCN) activity of secondary organic aerosol (SOA) generated from ozonolysis of β-caryophyllene was characterized by determining the CCN derived hygroscopicity parameter, κCCN, from experimental data. Two types of CCN counters, operating at different temperatures, were used. The effect of semi-volatile organic compounds on the CCN activity of SOA was studied using a thermodenuder. Overall, SOA was only slightly CCN active (with κCCN in the range 0.001–0.16), and in dark experiments with no OH scavenger present, κCCN decreased when particles were sent through the thermodenuder (with a temperature up to 50 °C). SOA was generated under different experimental conditions: In some experiments, an OH scavenger (2-butanol) was added. SOA from these experiments was less CCN active than SOA produced in experiments without an OH scavenger (i.e. where OH was produced during ozonolysis). In other experiments, lights were turned on, either without or with the addition of HONO (OH source). This led to the formation of more CCN active SOA. SOA was aged up to 30 h through exposure to ozone and (in experiments with no OH scavenger present) to OH. In all experiments, the derived κCCN consistently increased with time after initial injection of β-caryophyllene, showing that chemical ageing increases the CCN activity of β-caryophyllene SOA. κCCN was also observed to depend on supersaturation, which was explained either as an evaporation artifact from semi-volatile SOA (only observed in experiments lacking light exposure) or, alternatively, by effects related to chemical composition depending on dry particle size. Using the method of Threshold Droplet Growth Analysis it was also concluded that the activation kinetics of the SOA do not differ significantly from calibration ammonium sulphate aerosol for particles aged for several hours.