Abstract. Characteristics and sources of volatile organic compounds (VOCs)
were investigated with highly time-resolved simultaneous measurements by two
proton-transfer-reaction time-of-flight mass spectrometers (PTR-ToF-MS) at
an urban and a suburban site in New Delhi, India, from January to March 2018. During the measurement period, high mixing ratios of VOCs and trace gases
were observed, with high nocturnal mixing ratios and strong day–night
variations. The positive matrix factorization (PMF) receptor model was
applied separately to the two sites, and six major factors of VOCs were
identified at both sites, i.e., two factors related to traffic emissions,
two to solid fuel combustion, and two secondary factors. At the urban site,
traffic-related emissions comprising mostly mono-aromatic compounds were the
dominant sources, contributing 56.6 % of the total mixing ratio, compared
to 36.0 % at the suburban site. Emissions from various solid fuel
combustion processes, particularly in the night, were identified as a
significant source of aromatics, phenols and furans at both sites. The
secondary factors accounted for 15.9 % of the total VOC concentration at
the urban site and for 33.6 % at the suburban site. They were dominated by
oxygenated VOCs and exhibited substantially higher contributions during
daytime.
The oxidative potential (OP) of ambient particulate matter (PM) is a commonly used metric to link the aerosol exposure to its adverse health effects. In this study, we report the first-ever real-time measurements of ambient PM2.5 OP based on a dithiothreitol (DTT) assay in Delhi, during a late winter season (February 2019). The chemical composition of PM was also measured using various collocated online instruments to identify the chemical components driving the PM2.5 OP. The hourly averaged OP during the entire campaign ranged from 0.49 -3.60 nmol/min/m 3 , with an average value of 1.57±0.7 nmol/min/m 3 . The secondary organic aerosols appear to be the major driver for the variability in the intrinsic OP of PM2.5. Although, the average PM1 mass concentration at Delhi was 13-times the average PM2.5 mass concentration reported in Illinois, USA in a similar study, it was not accompanied by a proportionate increase in the OP (average volume normalized DTT activity of PM2.5 was only 5 times of that reported in Illinois). These findings reveal substantial spatial heterogeneity in the redox properties of PM and highlight the importance of determining the PM chemical composition along with its mass concentrations for predicting the overall health impacts associated with aerosol exposure.
Intramolecular C–N heterocyclization and C–C bond formation under visible light irradiation at room temperature was accomplished with a metal-free photoredox catalyst.
Aerosols play an important yet uncertain role in modulating the radiation balance of the sensitive Arctic atmosphere. Organic aerosol is one of the most abundant, yet least understood, fractions of the Arctic aerosol mass. Here we use data from eight observatories that represent the entire Arctic to reveal the annual cycles in anthropogenic and biogenic sources of organic aerosol. We show that during winter, the organic aerosol in the Arctic is dominated by anthropogenic emissions, mainly from Eurasia, which consist of both direct combustion emissions and long-range transported, aged pollution. In summer, the decreasing anthropogenic pollution is replaced by natural emissions. These include marine secondary, biogenic secondary and primary biological emissions, which have the potential to be important to Arctic climate by modifying the cloud condensation nuclei properties and acting as ice-nucleating particles. Their source strength or atmospheric processing is sensitive to nutrient availability, solar radiation, temperature and snow cover. Our results provide a comprehensive understanding of the current pan-Arctic organic aerosol, which can be used to support modelling efforts that aim to quantify the climate impacts of emissions in this sensitive region.
Abstract. The measurement of elements in PM10 was performed with 1 h time resolution at a rural freeway site during summer 2015 in Switzerland using the Xact1 625 Ambient Metals Monitor. On average the Xact elements (without accounting for oxygen and other associated elements) make up about 20 % of the total PM10 mass (14.6 µg m−3). We conducted source apportionment by positive matrix factorisation (PMF) of the
elemental mass measurable by the Xact (i.e. major elements heavier than
Al), defined here as PM10el. Eight different sources were identified in PM10el (elemental PM10) mass driven by the sum of 14 elements (notable elements in brackets): Fireworks-I (K, S, Ba and Cl), Fireworks-II (K), sea salt (Cl), secondary sulfate (S), background dust (Si, Ti), road dust (Ca), non-exhaust traffic-related elements (Fe) and industrial elements (Zn and Pb). The major components were secondary sulfate and non-exhaust traffic-related elements followed by background dust and road dust factors, explaining 21 %, 20 %, 18 % and 16 % of the analysed PM10 elemental mass, respectively, with the factor mass not corrected for oxygen content. Further, there were minor contributions (on the order of a few percent) of sea salt and industrial sources. The regionally influenced secondary sulfate factor showed negligible resuspension, and concentrations were similar throughout the day. The significant loads of the non-exhaust traffic-related and road dust factors with strong diurnal variations highlight the continuing importance of vehicle-related air pollutants at this site. Enhanced control of PMF implemented via the SourceFinder software (SoFi Pro version 6.2, PSI, Switzerland) allowed for a successful apportionment of transient sources such as the two firework factors and sea salt, which remained mixed when analysed by unconstrained PMF.
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