Large quantities of mineral dust particles are frequently ejected into the atmosphere through the action of wind. The surface of dust particles acts as a sink for many gases, such as sulfur dioxide. It is well known that under most conditions, sulfur dioxide reacts on dust particle surfaces, leading to the production of sulfate ions. In this report, for specific atmospheric conditions, we provide evidence for an alternate pathway in which a series of reactions under solar UV light produces first gaseous sulfuric acid as an intermediate product before surface-bound sulfate. Metal oxides present in mineral dust act as atmospheric photocatalysts promoting the formation of gaseous OH radicals, which initiate the conversion of SO
2
to H
2
SO
4
in the vicinity of dust particles. Under low dust conditions, this process may lead to nucleation events in the atmosphere. The laboratory findings are supported by recent field observations near Beijing, China, and Lyon, France.
We report on experiments that probe
photosensitized chemistry at
the air/water interface, a region that does not just connect the two
phases but displays its own specific chemistry. Here, we follow reactions
of octanol, a proxy for environmentally relevant soluble surfactants,
initiated by an attack by triplet-state carbonyl compounds, which
are themselves concentrated at the interface by the presence of this
surfactant. Gas-phase products are determined using PTR-ToF-MS, and
those remaining in the organic layer are determined by ATR-FTIR spectroscopy
and HPLC-HRMS. We observe the photosensitized production of carboxylic
acids as well as unsaturated and branched-chain oxygenated products,
compounds that act as organic aerosol precursors and had been thought
to be produced solely by biological activity. A mechanism that is
consistent with the observations is detailed here, and the energetics
of several key reactions are calculated using quantum chemical methods.
The results suggest that the concentrating nature of the interface
leads to its being a favorable venue for radical reactions yielding
complex and functionalized products that themselves could initiate
further secondary chemistry and new particle formation in the atmospheric
environment.
SSCI-VIDE+CARE+JSH:MPI:YDU:RCI:LTI:SRS:CGOInternational audienceOrganosulfates are tracers for secondary organic aerosol (SOA) formation. We propose a new mechanism of organosulfur product formationin the atmosphere, in which sulfur dioxide (SO2) reacts directly withalkenes. The experiments were conducted at the gas-liquid interface witha coated-wall flow tube reactor. It was shown, for the first time, thatSO2 reacts efficiently with the unsaturated bond in oleic acid underatmospheric conditions (without ozone), leading to the formation of C-9and C-18 organosulfur products. The associated uptake coefficients werein excess of 10(-6), decreasing with initial SO2 concentration andincreasing with humidity. These results might explain a fraction oforganosulfur products detected in atmospheric particles. This work tendsto elucidate the role of organosulfates' interfacial chemistry as apotentially unrecognized pathway for their contribution to SOAformation; however, it remains to be determined how significant thispathway is to the overall organosulfate abundances measured in ambientaerosol
The heterogeneous reaction between SO2 and unsaturated compounds results in the efficient production of organosulfates for several fatty acids and long-chain alkenes. The presence of an acid group, the physical state of the reactants (solid or liquid), the nature of the double bond (cis, trans, terminal), and the use of light irradiation all have an impact on the reaction rate. The reaction was investigated using different set-ups (coated flow tube, aerosol flow tube, and diffuse reflectance infrared Fourier transform cell). The reaction products were identified by high-resolution mass spectrometry and the impact of this reaction on organosulfate formation in the atmosphere is discussed.
During the European Life+ project PhotoPAQ (Demonstration of Photocatalytic remediation Processes on Air Quality), photocatalytic remediation of nitrogen oxides (NOx), ozone (O3), volatile organic compounds (VOCs), and airborne particles on photocatalytic cementitious coating materials was studied in an artificial street canyon setup by comparing with a colocated nonactive reference canyon of the same dimension (5 × 5 × 53 m). Although the photocatalytic material showed reasonably high activity in laboratory studies, no significant reduction of NOx, O3, and VOCs and no impact on particle mass, size distribution, and chemical composition were observed in the field campaign. When comparing nighttime and daytime correlation plots of the two canyons, an average upper limit NOx remediation of ≤2% was derived. This result is consistent only with three recent field studies on photocatalytic NOx remediation in the urban atmosphere, whereas much higher reductions were obtained in most other field investigations. Reasons for the controversial results are discussed, and a more consistent picture of the quantitative remediation is obtained after extrapolation of the results from the various field campaigns to realistic main urban street canyon conditions.
Organic interfaces that exist at the sea surface microlayer or as surfactant coatings on cloud droplets are highly concentrated and chemically distinct from the underlying bulk or overlying gas phase. Therefore, they may be potentially unique locations for chemical or photochemical reactions. Recently, photochemical production of volatile organic compounds (VOCs) was reported at a nonanoic acid interface however, subsequent secondary organic aerosol (SOA) particle production was incapable of being observed. We investigated SOA particle formation due to photochemical reactions occurring at an air-water interface in presence of model saturated long chain fatty acid and alcohol surfactants, nonanoic acid and nonanol, respectively. Ozonolysis of the gas phase photochemical products in the dark or under continued UV irradiation both resulted in nucleation and growth of SOA particles. Irradiation of nonanol did not yield detectable VOC or SOA production. Organic carbon functionalities of the SOA were probed using X-ray microspectroscopy and compared with other laboratory generated and field collected particles. Carbon-carbon double bonds were identified in the condensed phase which survived ozonolysis during new particle formation and growth. The implications of photochemical processes occurring at organic coated surfaces are discussed in the context of marine SOA particle atmospheric fluxes.
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