This study investigates the contribution
of high-molecular weight
dimer esters to laboratory-generated α-pinene gas- and particle-phase
secondary organic aerosol (SOA) and particulate matter (PM) collected
at the Nordic boreal forest site of Hyytiälä, Finland.
Laboratory flow reactor experiments (25 °C) show that dimer esters
from ozonolysis of α-pinene contribute between 5 and 16% of
the freshly formed α-pinene particle-phase SOA mass. An increased
level of formation is observed at a higher relative humidity of ∼40%,
and the presence of a hydroxyl radical (OH) scavenger is shown to
affect the formation of dimer esters. Of the 28 dimer esters identified
in laboratory α-pinene SOA, 15 are also observed in ambient
PM samples, contributing between 0.5 and 1.6% of the total PM1. The observed esters show good correlation with known α-pinene
SOA tracers in collected PM samples. This work reveals an, until now,
unrecognized contribution of dimer esters from α-pinene oxidation
to boreal forest PM.
Secondary organic aerosol (SOA) represents a significant fraction of the tropospheric aerosol and its precursors are volatile organic compounds (VOCs). Anthropogenic VOCs (AVOC) dominate the VOC budget in many urban areas with 1,3,5-trimethylbenzene (TMB) being among the most reactive aromatic AVOCs. TMB formed highly oxygenated organic molecules (HOMs) in an NO x -free environment, which could contribute to new particle formation (NPF) depending on oxidation conditions where elevated OH oxidation enhanced particle formation. The experiments were performed in an oxidation flow reactor, the Go:PAM unit, under controlled OH oxidation conditions. By addition of NO x to the system we investigated the effect of NO x on particle formation and on the product distribution. We show that the formation of HOMs, and especially HOM accretion products, strongly varies with NO x conditions. We observe a suppression of HOM and particle formation with increasing NO x / TMB ratio and an increase in the formation of organonitrates (ONs) mostly at the expense of HOM accretion products. We propose reaction mechanisms and pathways that explain the formation and observed product distributions with respect to oxidation conditions. We hypothesise that, based on our findings from TMB oxidation studies, aromatic AVOCs may not contribute significantly to NPF under typical NO x /AVOC conditions found in urban atmospheres.
Abstract. The gas-phase nitrate radical (NO q 3 ) initiated oxidation of limonene can produce organic nitrate species with varying physical properties. Low-volatility products can contribute to secondary organic aerosol (SOA) formation and organic nitrates may serve as a NO x reservoir, which could be especially important in regions with high biogenic emissions. This work presents the measurement results from flow reactor studies on the reaction of NO q 3 with limonene using a High-Resolution Time-of-Flight Chemical Ionization Mass Spectrometer (HR-ToF-CIMS) combined with a Filter Inlet for Gases and AEROsols (FIGAERO). Major condensed-phase species were compared to those in the Master Chemical Mechanism (MCM) limonene mechanism, and many non-listed species were identified. The volatility properties of the most prevalent organic nitrates in the produced SOA were determined. Analysis of multiple experiments resulted in the identification of several dominant species (including C 10 H 15 NO 6 , C 10 H 17 NO 6 , C 8 H 11 NO 6 , C 10 H 17 NO 7 , and C 9 H 13 NO 7 ) that occurred in the SOA under all conditions considered. Additionally, the formation of dimers was consistently observed and these species resided almost completely in the particle phase. The identities of these species are discussed, and formation mechanisms are proposed. Cluster analysis of the desorption temperatures corresponding to the analyzed particle-phase species yielded at least five distinct groupings based on a combination of molecular weight and desorption profile. Overall, the results indicate that the oxidation of limonene by NO q 3 produces a complex mixture of highly oxygenated monomer and dimer products that contribute to SOA formation.
Abstract. The Filter Inlet for Gases and AEROsols (FIGAERO) is an inlet specifically
designed to be coupled with the Aerodyne High-Resolution Time-of-Flight
Chemical Ionization Mass Spectrometer (HR-ToF-CIMS). The FIGAERO-HR-ToF-CIMS
provides simultaneous molecular information relating to both the gas- and
particle-phase samples and has been used to extract vapour pressures (VPs) of
the compounds desorbing from the filter whilst giving quantitative
concentrations in the particle phase. However, such extraction of vapour
pressures of the measured particle-phase components requires use of
appropriate, well-defined, reference compounds. Vapour pressures for the
homologous series of polyethylene glycols (PEG)
((H-(O-CH2-CH2)n-OH) for n=3 to n=8), covering a range
of vapour pressures (VP) (10−1 to 10−7 Pa) that are
atmospherically relevant, have been shown to be reproduced well by a range of
different techniques, including Knudsen Effusion Mass Spectrometry (KEMS).
This is the first homologous series of compounds for which a number of vapour
pressure measurement techniques have been found to be in agreement,
indicating the utility as a calibration standard, providing an ideal set of
benchmark compounds for accurate characterization of the FIGAERO for
extracting vapour pressure of measured compounds in chambers and the real
atmosphere. To demonstrate this, single-component and mixture vapour pressure
measurements are made using two FIGAERO-HR-ToF-CIMS instruments based on a
new calibration determined from the PEG series. VP values extracted from both
instruments agree well with those measured by KEMS and reported values from
literature, validating this approach for extracting VP data from the FIGAERO.
This method is then applied to chamber measurements, and the vapour pressures
of known products are estimated.
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