The acidity of atmospheric particles and clouds

Acidity, defined as pH, is a central component of aqueous chemistry. In the atmosphere, the acidity of condensed phases (aerosol particles, cloud water, and fog droplets) governs the phase partitioning of semivolatile gases such as HNO3, NH3, HCl, and organic acids and bases as well as chemical reaction rates. It has implications for the atmospheric lifetime of pollutants, deposition, and human health. Despite its fundamental role in atmospheric processes, only recently has this field seen a growth in the number of studies on particle acidity. Even with this growth, many fine-particle pH estimates must be based on thermodynamic model calculations since no operational techniques exist for direct measurements. Current information indicates acidic fine particles are ubiquitous, but observationally constrained pH estimates are limited in spatial and temporal coverage. Clouds and fogs are also generally acidic, but to a lesser degree than particles, and have a range of pH that is quite sensitive to anthropogenic emissions of sulfur and nitrogen oxides, as well as ambient ammonia. Historical measurements indicate that cloud and fog droplet pH has changed in recent decades in response to controls on anthropogenic emissions, while the limited trend data for aerosol particles indicate acidity may be relatively constant due to the semivolatile nature of the key acids and bases and buffering in particles. This paper reviews and synthesizes the current state of knowledge on the acidity of atmospheric condensed phases, specifically particles and cloud droplets. It includes recommendations for estimating acidity and pH, standard nomenclature, a synthesis of current pH estimates based on observations, and new model calculations on the local and global scale.

Biomass-burning impact on CCN number, hygroscopicity and cloud formation during summertime in the eastern Mediterranean

Athanasios Nenes

This study investigates the concentration, cloud condensation nuclei (CCN) activity and hygroscopic properties of particles influenced by biomass burning in the eastern Mediterranean and their impacts on cloud droplet formation. Air masses sampled were subject to a range of atmospheric processing (several hours up to 3 days). Values of the hygroscopicity parameter, κ, were derived from CCN measurements and a Hygroscopic Tandem Differential Mobility Analyzer (HTDMA). An Aerosol Chemical Speciation Monitor (ACSM) was also used to determine the chemical composition and mass concentration of non-refractory components of the submicron aerosol fraction. During fire events, the increased organic content (and lower inorganic fraction) of the aerosol decreases the values of κ, for all particle sizes. Particle sizes smaller than 80 nm exhibited considerable chemical dispersion (where hygroscopicity varied up to 100% for particles of same size); larger particles, however, exhibited considerably less dispersion owing to the effects of condensational growth and cloud processing. ACSM measurements indicate that the bulk composition reflects the hygroscopicity and chemical nature of the largest particles (having a diameter of ∼ 100 nm at dry conditions) sampled. Based on positive matrix factorization (PMF) analysis of the organic ACSM spectra, CCN concentrations follow a similar trend as the biomass-burning organic aerosol (BBOA) component, with the former being enhanced between 65 and 150% (for supersaturations ranging between 0.2 and 0.7%) with the arrival of the smoke plumes. Using multilinear regression of the PMF factors (BBOA, OOA-BB and OOA) and the observed hygroscopicity parameter, the inferred hygroscopicity of the oxygenated organic aerosol components is determined. We find that the transformation of freshly emitted biomass burning (BBOA) to more oxidized organic aerosol (OOA-BB) can result in a 2-fold increase of the inferred organic hygroscopicity; about 10% of the total aerosol hygroscopicity is related to the two biomass-burning components (BBOA and OOA-BB), which in turn contribute almost 35% to the fine-particle organic water of the aerosol. Observation-derived calculations of the cloud droplet concentrations that develop for typical boundary layer cloud conditions suggest that biomass burning increases droplet number, on average by 8.5%. The strongly sublinear response of clouds to biomass-burning (BB) influences is a result of strong competition of CCN for water vapor, which results in very low maximum supersaturation (0.08% on average). Attributing droplet number variations to the total aerosol number and the chemical composition variations shows that the importance of chemical composition increases with distance, contributing up to 25% of the total droplet variability. Therefore, although BB may strongly elevate CCN numbers, the impact on droplet number is limited by water vapor availability and depends on the aerosol particle concentration levels associated with the background. © 2016 Author(s).

Copernicus GmbH2016

Size-resolved aerosol pH over Europe during summer

Athanasios Nenes

The dependence of aerosol acidity on particle size, location, and altitude over Europe during a summertime period is investigated using the hybrid version of aerosol dynamics in the chemical transport model PMCAMx. The pH changes more with particle size in northern and southern Europe owing to the enhanced presence of non-volatile cations (Na, Ca, K, Mg) in the larger particles. Differences of up to 1-4 pH units are predicted between sub- and supermicron particles, while the average pH of PM1-2.5 can be as much as 1 unit higher than that of PM1. Most aerosol water over continental Europe is associated with PM1, while coarse particles dominate the water content in the marine and coastal areas due to the relatively higher levels of hygroscopic sea salt. Particles of all sizes become increasingly acidic with altitude (0.5-2.5 units pH decrease over 2.5 km) primarily because of the decrease in aerosol liquid water content (driven by humidity changes) with height. Inorganic nitrate is strongly affected by aerosol pH with the highest average nitrate levels predicted for the PM1-5 range and over locations where the pH exceeds 3. Dust tends to increase aerosol pH for all particle sizes and nitrate concentrations for supermicron range particles. This effect of dust is quite sensitive to its calcium content. The size-dependent pH differences carry important implications for pH-sensitive processes in the aerosol.

COPERNICUS GESELLSCHAFT MBH2021

Reactions of nitrogen-containing compounds with ozone: kinetics and mechanisms

Sung Eun Lim

Nitrogen-containing moieties are widespread in natural waters in dissolved organic nitrogen and micropollu-tants. They are often susceptible to an electrophilic attack of ozone because of the electron-rich nature of the neutral form of nitrogen in organic compounds. This indicates that reactions of nitrogen-containing compounds with ozone inevitably occur in water and wastewater treatment where ozonation is applied for disinfection or oxidation. Despite the relevance to ozone chemistry, the knowledge on reactions of ozone with some principal nitrogen-containing functional groups is limited. The aim of this thesis was to elucidate reaction mechanisms of nitrogen-containing compounds with ozone for common nitrogen-containing functional groups: aliphatic amines and azoles. The primary objectives were (1) to determine the second-order rate constants for the reactions of nitrogen-containing compounds with ozone (kO3), (2) to identify/quantify transformation products and reactive oxygen species, (3) to perform kinetic simulations and quantum chemical computations to supplement or corroborate empirical evidences. Reaction mechanisms were proposed by compiling the results from all aspects, providing a better understanding of nitrogen-ozone chemistry. The investigation of triethylamine, diethylamine, and ethylamine yielded kO3 of the neutral form of amines ranging from 9.310^4 M-1 s-1 to 2.210^6 M-1 s-1. The apparent kO3 at pH 7 for potential or identified transformation products were 6.810^5 M-1 s-1 for N,N-diethylhydroxylamine, ~10^5 M-1 s-1 for N-ethylhydroxylamine, 1.910^3 M-1 s-1 for N-ethylethanimine oxide, and 3.4 M-1 s-1 for nitroethane. All amines predominantly underwent oxygen-transfer pathways to form major transformation products containing nitrogen-oxygen bonds: triethylamine N-oxide (88% per abated triethylamine) and nitroethane (69% per abated diethylamine and 100% per abate ethylamine). N,N-diethylhydroxylamine was a potential primary transformation product during the diethylamine-ozone reaction. Its formation was not confirmed due to its high ozone reactivity, but supported by measurements of reactive oxygen species, kinetic simulations, and quantum chemical computations. Pyrrole and imidazole reacted fast (kO3 > 10^3 M-1 s-1 at pH 1 â 12), whereas pyrazole reacted moderately fast with ozone (kO3 = 56 M-1 s-1 at pH 7). All studied azoles underwent an addition of ozone to the C-C double bond in the ring. Subsequent pathways after the initial ozone addition varied considerably among the azoles. Pyrrole reacted with ozone via a Criegee-type and an oxygen-addition mechanism. The major identified products (yield per abated pyrrole) were maleimide (34%), formamide (14%) and formate (54%). Imidazole predominantly reacted via a Criegee-type mechanism with ring cleavage and formation of the three fragments, formamide, cyanate, and formate (~100 % yields, respectively), completely closing the mass balance. For pyrazole, only carbonous products were identified (126% formate and 34% glyoxal per abated pyrazole). Products containing hydroxypyrazole and hydrazide moieties were postulated, possibly formed via an oxygen addition and a Criegee-type mechanism, respectively. The nitrogenous transformation products identified during this study may have different environmental implications. Some of them (e.g., nitroalkanes, N-formyl compounds) require further efforts to understand their impact on the aquatic environment and human health.

EPFL2020

Biomass-burning impact on CCN number, hygroscopicity and cloud formation during summertime in the eastern Mediterranean

Athanasios Nenes

Copernicus GmbH2016

Reactions of nitrogen-containing compounds with ozone: kinetics and mechanisms

Sung Eun Lim

EPFL2020