Quantitative assessment of organosulfates in size-segregated rural fine aerosol

Lukács, H.; Gelencsér, András; Hoffer, András; Kiss, Gyula; Horváth, Krisztián; Hartyáni, Zsuzsanna

doi:10.5194/acpd-8-6825-2008

Cited by 15 publications

(29 citation statements)

References 35 publications

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“…Despite the uncertainties associated with this estimate, it is clear that organosulfates may be responsible for a sizable fraction of ambient OM. In addition to our estimates, Lukács et al 64 recently showed that organosulfates in watersoluble fine aerosol, also collected from the K-puszta field site during the 2006 summer campaign, contribute 6-12% to the total sulfur concentration. Due to the likely importance of these estimates, it is essential that the detailed chemical characterization of organosulfates be conducted as this will lead to improved understanding of their formation pathways in ambient organic aerosol.…”

Section: Atmospheric Significance Of Organosulfatesmentioning

confidence: 75%

“…Furthermore, it has been suggested that organosulfate formation occurs on the acidic surface (and not in the bulk) of a fine ambient aerosol particle as a result of condensation of semivolatile organic vapors and subsequent reaction with sulfuric acid and gives rise to a refractory organic film. 64,95 It would be worthwhile to confirm in further studies with suitable analytical techniques (e.g., transmission electron microscopy) the occurrence of organosulfates on the surface of ambient fine aerosols.…”

Section: Discussionmentioning

confidence: 98%

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Organosulfate Formation in Biogenic Secondary Organic Aerosol

et al. 2008

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Organosulfates of isoprene, alpha-pinene, and beta-pinene have recently been identified in both laboratory-generated and ambient secondary organic aerosol (SOA). In this study, the mechanism and ubiquity of organosulfate formation in biogenic SOA is investigated by a comprehensive series of laboratory photooxidation (i.e., OH-initiated oxidation) and nighttime oxidation (i.e., NO3-initiated oxidation under dark conditions) experiments using nine monoterpenes (alpha-pinene, beta-pinene, d-limonene, l-limonene, alpha-terpinene, gamma-terpinene, terpinolene, Delta(3)-carene, and beta-phellandrene) and three monoterpenes (alpha-pinene, d-limonene, and l-limonene), respectively. Organosulfates were characterized using liquid chromatographic techniques coupled to electrospray ionization combined with both linear ion trap and high-resolution time-of-flight mass spectrometry. Organosulfates are formed only when monoterpenes are oxidized in the presence of acidified sulfate seed aerosol, a result consistent with prior work. Archived laboratory-generated isoprene SOA and ambient filter samples collected from the southeastern U.S. were reexamined for organosulfates. By comparing the tandem mass spectrometric and accurate mass measurements collected for both the laboratory-generated and ambient aerosol, previously uncharacterized ambient organic aerosol components are found to be organosulfates of isoprene, alpha-pinene, beta-pinene, and limonene-like monoterpenes (e.g., myrcene), demonstrating the ubiquity of organosulfate formation in ambient SOA. Several of the organosulfates of isoprene and of the monoterpenes characterized in this study are ambient tracer compounds for the occurrence of biogenic SOA formation under acidic conditions. Furthermore, the nighttime oxidation experiments conducted under highly acidic conditions reveal a viable mechanism for the formation of previously identified nitrooxy organosulfates found in ambient nighttime aerosol samples. We estimate that the organosulfate contribution to the total organic mass fraction of ambient aerosol collected from K-puszta, Hungary, a field site with a similar organosulfate composition as that found in the present study for the southeastern U.S., can be as high as 30%.

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Section: Atmospheric Significance Of Organosulfatesmentioning

confidence: 75%

Section: Discussionmentioning

confidence: 98%

Organosulfate Formation in Biogenic Secondary Organic Aerosol

et al. 2008

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“…To our knowledge, organosulfate formation by methylglyoxal in ammonium sulfate aerosols has not been observed previously, although Liggio et al (2005a, b) and Galloway et al (2009) identified organosulfate products in ammonium sulfate aerosols exposed to gas-phase glyoxal. Organosulfates have been identified in ambient aerosol (Gao et al, 2006;Iinuma et al, 2007;Gómez-González et al, 2008;Surratt et al, 2007Surratt et al, , 2008Russell et al, 2009;Lukács et al, 2009). Lukács et al (2009) observed that organosulfate mass concentrations were at a maximum for submicron aerosol size fractions, suggesting a link between organosulfate formation and heterogeneous SOA formation pathways.…”

Section: Conclusion and Atmospheric Implicationsmentioning

confidence: 99%

“…Organosulfates have been identified in ambient aerosol (Gao et al, 2006;Iinuma et al, 2007;Gómez-González et al, 2008;Surratt et al, 2007Surratt et al, , 2008Russell et al, 2009;Lukács et al, 2009). Lukács et al (2009) observed that organosulfate mass concentrations were at a maximum for submicron aerosol size fractions, suggesting a link between organosulfate formation and heterogeneous SOA formation pathways. If C-N species form in this system, this could contribute to the nitrogen-containing aerosol organics which have been observed in ambient aerosol (Denkenberger et al, 2007;Aiken et al, 2008;Lin et al, 2009;Gilardoni et al, 2009).…”

Section: Conclusion and Atmospheric Implicationsmentioning

confidence: 99%

Secondary organic material formed by methylglyoxal in aqueous aerosol mimics – Part 1: Surface tension depression and light-absorbing products

Schwier¹,

Shapiro²,

Sareen³

et al. 2009

Preprint

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Abstract. We show that methylglyoxal forms light-absorbing secondary organic material in aqueous ammonium sulfate and ammonium nitrate solutions mimicking tropospheric aerosol particles. The light-absorbing products form on the order of minutes, and solution composition continues to change over several days. The results suggest an aldol condensation pathway involving the participation of the ammonium ion. Aqueous solutions of methylglyoxal, with and without inorganic salts, exhibit surface tension depression. Methylglyoxal uptake could potentially change the optical properties, climate effects, and heterogeneous chemistry of the seed aerosol over its lifetime.

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“…Consequently, natural marine aerosols are largely comprised of sea‐salt, sulfate, and organic material generated from the oxidation of marine biogenic gases, predominantly DMS, and combinations therein (Davison et al., 1996; Frossard et al., 2014; Quinn et al., 2014). DMS is converted to CCN through multiple cascades of chemical pathways, many of which are only vaguely understood, but biogenic activity related to CCN production is indicated by elevated concentrations of DMS and methane sulfonic acid (MSA), which is a reaction product (Bardouki et al., 2003; Barone et al., 1995; Gaston et al., 2010; Hodshire et al., 2019; Lukács et al., 2009). The oxidation of DMS into sulfuric acid (H 2 SO 4 ) within the MBL and the condensation of this H 2 SO 4 onto the surface of the smallest aerosol particles may reduce the critical radius such that it transforms the particles into viable CCN at reasonable supersaturations.…”

Section: Introductionmentioning

confidence: 99%

Observed Relationships Between Cloud Droplet Effective Radius and Biogenic Gas Concentrations in Summertime Marine Stratocumulus Over the Eastern North Atlantic

Miller

Mages

Zheng

et al. 2022

Earth and Space Science

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Biogenic gases are a prominent component of the summertime marine boundary layer (MBL) over the Eastern North Atlantic. One of these gases, dimethyl sulfide (DMS), can produce sulfate cloud condensation nuclei (CCN) that, in theory, can brighten clouds through photolysis, and produces a reaction product, methane sulfonic acid (MSA). It is also possible that DMS can interact with sea‐salt or other marine aerosols changing their CCN activation spectrum, which could also modify cloud microphysical structure. Data collected aboard the G1 aircraft during the Aerosol Cloud Experiment Eastern North Atlantic (ACE‐ENA) in well‐mixed and decoupled marine boundary layers (MBLs) were used to examine relationships between the cloud droplet effective radii, re ${r}_{e}$, and the concentrations of DMS and MSA in constant cloud liquid water content (LWC) bins. A weak but statistically significant negative correlation was observed between CCN concentration and re ${r}_{e}$ in most LWC bins, regardless of the source of the CCN, while a weak but statistically significant positive correlation between re ${r}_{e}$ and DMS was observed. No correlation between the cloud droplet number concentration and DMS was found. The presence of MSA indicated that DMS‐to‐sulfate photolysis was likely occurring, but data sparsity prevented a statistically significant conclusion regarding the relationship between MSA and re ${r}_{e}$. Data sparsity in decoupled conditions also prevented statistically significant conclusions. To properly address biogenic gas impacts on cloud microphysics, it is recommended that aircraft data be supplemented by long‐term biogenic gas measurements at the surface in marine locations with appropriate remote and in‐situ cloud sensing capabilities, and the analysis limited to well‐mixed MBL's.

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Quantitative assessment of organosulfates in size-segregated rural fine aerosol

Cited by 15 publications

References 35 publications

Organosulfate Formation in Biogenic Secondary Organic Aerosol

Organosulfate Formation in Biogenic Secondary Organic Aerosol

Secondary organic material formed by methylglyoxal in aqueous aerosol mimics – Part 1: Surface tension depression and light-absorbing products

Observed Relationships Between Cloud Droplet Effective Radius and Biogenic Gas Concentrations in Summertime Marine Stratocumulus Over the Eastern North Atlantic

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