Characterizing source fingerprints and ageing processes in laboratory-generated secondary organic aerosols using proton-nuclear magnetic resonance (&amp;lt;sup&amp;gt;1&amp;lt;/sup&amp;gt;H-NMR) analysis and HPLC HULIS determination

Zanca, Nicola; Lambe, Andrew T.; Massoli, P.; Paglione, Marco; Croasdale, D. R.; Parmar, Yatish; Tagliavini, Emilio; Gilardoni, Stefania; Decesari, Stefano

doi:10.5194/acp-17-10405-2017

Cited by 18 publications

(13 citation statements)

References 81 publications

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“…The specific fluorescence area was widened in the ambient sample and, thus, had a higher AFI/WSOC ratio when WSOC concentrations were at a comparable level. The continuous oxidation of organics may break up the π system of organics and extinct fluorescence (Zanca et al, 2017). It could be inferred that ambient WSOCs tended to exhibit higher AFI/WSOC ratios, whereas both freshly emitted WSOCs and completely oxidized WSOCs could lead to lower AFI/WSOC values.…”

Section: Discussionmentioning

confidence: 99%

Measurement report: Particle-size-dependent fluorescence properties of water-soluble organic compounds (WSOCs) and their atmospheric implications for the aging of WSOCs

et al. 2022

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Abstract. Water-soluble organic compounds (WSOCs) play important roles in atmospheric particle formation, migration, and transformation processes. Size-segregated atmospheric particles were collected in a rural area of Beijing. Three-dimensional fluorescence spectroscopy was used to investigate the optical properties of WSOCs as a means of inferring information about their atmospheric sources. Sophisticated analysis on fluorescence data was performed to characteristically estimate the connections among particles of different sizes. WSOC concentrations and the average fluorescence intensity (AFI) showed a monomodal distribution in winter and a bimodal distribution in summer, with the dominant mode in the 0.26–0.44 µm size range in both seasons. The excitation–emission matrix (EEM) spectra of WSOCs varied with particle size, likely due to changing sources and/or the chemical transformation of organics. Size distributions of the fluorescence regional integration (regions III and V) and humification index (HIX) indicate that the humification degree or aromaticity of WSOCs was the highest in the particle size range of 0.26–0.44 µm. The Stokes shift (SS) and the harmonic mean of the excitation and emission wavelengths (WH) reflected that π-conjugated systems were high in the same particle size range. The parallel factor analysis (PARAFAC) results showed that humic-like substances were abundant in fine particles (< 1 µm) and peaked at 0.26–0.44 µm. All evidence supported the fact that the humification degree of WSOCs increased with particle size in the submicron mode (< 0.44 µm) and then decreased gradually with particle size, which implied that the condensation of organics occurred in submicron particles, resulting in the highest degree of humification in the particle size range of 0.26–0.44 µm rather than in the < 0.26 µm range. Synthetically analyzing three-dimensional fluorescence data could efficiently reveal the secondary transformation processes of WSOCs.

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Section: Discussionmentioning

confidence: 99%

Measurement report: Particle-size-dependent fluorescence properties of water-soluble organic compounds (WSOCs) and their atmospheric implications for the aging of WSOCs

et al. 2022

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“…To establish photooxidation conditions, the O 3 was photolyzed at λ of 254 nm inside the OFR to generate O( 1 D) radicals, which reacted with H 2 O to continuously produce hydroxyl (OH) radicals ([OH] ≈ 10 10 cm –3 ). Recent studies suggest that SOA particles generated in OFRs have compositions similar to SOA generated in environmental chambers ,− and in the atmosphere. − …”

Section: Methodsmentioning

confidence: 99%

Reactive Uptake of Isoprene Epoxydiols Increases the Viscosity of the Core of Phase-Separated Aerosol Particles

Olson

Lei

Craig

et al. 2019

ACS Earth Space Chem.

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102

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Atmospheric oxidation of volatile organic compounds, such as isoprene, and subsequent condensation or heterogeneous reactions lead to the formation of secondary organic aerosol (SOA), a ubiquitous component of submicron aerosol. Liquid–liquid phase-separated organic–inorganic aerosol particles have been observed in the laboratory and field; however, the impacts of multiphase reactions on aerosol viscosity are not well understood for phase-separated aerosol particles. In this study, phase-separated aerosol particles were reacted with gaseous isoprene epoxydiol (IEPOX), an abundant isoprene oxidation product. Acidic sulfate particles (H2SO4 + (NH4)2SO4 at pH = 1.4) were coated with laboratory-generated biogenic SOA (α-pinene + O3) and anthropogenic SOA (toluene + OH), resulting in a core–shell morphology. After reaction with IEPOX, the phase-separated aerosol particles no longer displayed characteristics of a liquid core. Instead, they became irregularly shaped, taller after impaction onto substrates, and had decreased spreading ratios for both types of SOA, implying an increase in particle viscosity. As the SOA from α-pinene and toluene was already viscous, this is indicative of a change in phase state for the core from liquid to viscous state. An example reaction that may be facilitating this phase change is IEPOX reaction with inorganic sulfate to produce organosulfates, especially after IEPOX diffuses through the organic coating. The modification of the aerosol physicochemical properties suggests that phase state is dynamic over the atmospheric lifetime of SOA-containing particles, with multiphase chemistry between aerosol particles and gaseous species leading to more viscous aerosol after uptake of isoprene oxidation products (e.g., IEPOX).

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“…Another study reported increased RNA oxidation in cells exposed to SOA resulting in transcript alteration and cell function disruption . Some molecules namely cinnamic acid, hydroxybenzoic acid, and 1,4-naphtaquinone were found in SOA, − and they or their derivatives have been reported to induce apoptosis and autophagy in multiples cancer cells lines. − …”

Section: Pathogenic Impact Of Soamentioning

confidence: 99%

Pathogenic Mechanisms of Secondary Organic Aerosols

Déméautis

Delles

Tomaz

et al. 2022

Chem. Res. Toxicol.

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Air pollution represents a major health problem and an economic burden. In recent years, advances in air pollution research has allowed particle fractionation and identification of secondary organic aerosol (SOA). SOA is formed from either biogenic or anthropogenic emissions, through a mass transfer from the gaseous mass to the particulate phase in the atmosphere. They can have deleterious impact on health and the mortality of individuals with chronic inflammatory diseases. The pleiotropic effects of SOA could involve different and interconnected pathogenic mechanisms ranging from oxidative stress, inflammation, and immune system dysfunction. The purpose of this review is to present recent findings about SOA pathogenic roles and potential underlying mechanisms focusing on the lungs; the latter being the primary exposed organ to atmospheric pollutants.

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Characterizing source fingerprints and ageing processes in laboratory-generated secondary organic aerosols using proton-nuclear magnetic resonance (<sup>1</sup>H-NMR) analysis and HPLC HULIS determination

Cited by 18 publications

References 81 publications

Measurement report: Particle-size-dependent fluorescence properties of water-soluble organic compounds (WSOCs) and their atmospheric implications for the aging of WSOCs

Measurement report: Particle-size-dependent fluorescence properties of water-soluble organic compounds (WSOCs) and their atmospheric implications for the aging of WSOCs

Reactive Uptake of Isoprene Epoxydiols Increases the Viscosity of the Core of Phase-Separated Aerosol Particles

Pathogenic Mechanisms of Secondary Organic Aerosols

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