Glyoxal in Aqueous Ammonium Sulfate Solutions: Products, Kinetics and Hydration Effects

Yu, Ge; Bayer, Amanda R.; Galloway, Melissa M.; Korshavn, Kyle J.; Fry, Charles G.; Keutsch, Frank N.

doi:10.1021/es200989n

Cited by 229 publications

(484 citation statements)

References 36 publications

(74 reference statements)

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“…Formic acid, especially under acidic conditions, is a sufficiently strong reducing agent to complete the reductive amination step as shown in Scheme 1. Formic acid was not 30 detected in this study in either positive or negative ion mode (as m/z 47 or 45, respectively) but it has been reported as a side product of glyoxal/AS and methyglyoxal/AS in several other studies (Galloway et al, 2009;De Haan et al, 2009;Sareen et al, 2010;Yu et al, 2011). The evidence outlined here lends confidence to our assignment of m/z 109 as 2,5-DMP.…”

Section: Pyrazine-based Chromophoressupporting

confidence: 77%

“…In our study, absorbance has been normalized by TOC concentration for each sample to provide a bulk solution phase mass absorption coefficient, 25 which accounts for the loss of any organic carbon to the gas phase. The results in Figure 1a are consistent with Kampf et al (2012) and Yu et al (2011) and suggest that over a pH range between 2 and 9, the role of nitrogen as a nucleophile is more important for chromophore formation than acid-catalyzed aldol condensation. The observed changes in absorptivity (rather than absorbance) imply that solution pH can promote one product (like methylglyoxal self-reaction products) at the expense of another (N-containing products) or that unreacted methylglyoxal remains in solution after one week.…”

Section: Role Of Ph In Chromophore Formationsupporting

confidence: 76%

“…In a related study, Kampf et al (2012) observed a novel, highly absorptive chromophore in the glyoxal/ammonium sulfate system, the imidazole bicycle, whose production 5 rate declined as the pH of the reaction dropped. Similarly, Yu et al (2011) observed an exponential dependence on pH for the rate of formation of imidazole and related products and concluded that available ammonia, dictated by solution pH, drives this relationship. In the context of food chemistry, it is thought that neutral or slightly alkaline conditions favor melanoidins generally (Kwak et al, 2005) and in particular dimethylpyrazine (Koehler and Odell, 1970).…”

Section: Introductionmentioning

confidence: 93%

“…The mechanistic details of aqBrC formation, including the roles of pH and evaporation, are still incomplete, yet some trends in aqBrC absorptivity 30 have been identified. In most cases, it was concluded that chromophores form fastest in basic solution, because nitrogen (in ammonia, methylamine, or amino acids) must initiate a nucleophilic attack at the carbonyl carbon atom (Yu et al, 2011;Kampf et al, 2012). However, several studies have shown that aldol condensation of dicarbonyls can be acid catalyzed (Noziere et al, 2009) and that aldol condensation products may contribute to visible light absorption (Sareen et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

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Evidence for pyrazine-based chromophores in cloudwater mimics containing methylglyoxal and ammonium sulfate

Hawkins¹,

Welsh²,

Alexander³

2018

Preprint

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Abstract. Simulating aqueous brown carbon (aqBrC) formation from small molecule amines and aldehydes in cloud water mimics provides insight into potential humic-like substance (HULIS) contributors and their effect on local and global aerosol radiative forcing. Previous work has shown that these (Maillard type) reactions generate products that are chemically, physically, and optically similar to atmospheric HULIS in many significant ways, including in their complexity. Despite numerous characterization studies, attribution of the intense brown color of many aqBrC systems to specific compounds remains in-5 complete. In this work, we present evidence of novel pyrazine-based chromophores (PBC) in the product mixture of aqueous solutions containing methylglyoxal and ammonium sulfate. PBC observed here include 2,5-dimethyl pyrazine (DMP) and products of methylglyoxal addition to the pyrazine ring. This finding is significant as the literature of Maillard reactions in food chemistry tightly links the formation of pyrazine (and related compounds) to browning in foods. We investigated both the roles of cloud processing (by bulk evaporation) and pH on absorptivity and product distribution in microliter samples to 10 understand the contribution of these PBC to aqBrC properties. In agreement with previous work, we observed elevated absorptivity across the entire UV/visible spectrum following simulated cloud processing as well as higher absorptivity in more basic samples. Absorptivity of the pH 2 sample, following evaporation, exceeded that of the unevaporated pH 9 sample, indicating that cloud processing can overcome the previously observed kinetic barrier imposed on aqBrC formation in acidic conditions. Further, the fraction of pyrazine compounds in the product mixture increased by up to a factor of four in response to drying 15 with a maximum observed contribution of 16% at pH 5. Therefore, cloud processing under more acidic conditions may produce PBC at the expense of imine and imidazole-derived compounds. This finding has implications for further BrC reactivity and degradation pathways.1

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Section: Pyrazine-based Chromophoressupporting

confidence: 77%

Section: Role Of Ph In Chromophore Formationsupporting

confidence: 76%

Section: Introductionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Evidence for pyrazine-based chromophores in cloudwater mimics containing methylglyoxal and ammonium sulfate

Hawkins¹,

Welsh²,

Alexander³

2018

Preprint

View full text Add to dashboard Cite

show abstract

“…Atmospheric organic nitrogen can also be formed through chemical reactions. For example, reactions between volatile organic compounds, NO x and ammonium sulfate aerosols may lead to the formation of nitrogen-containing compounds (Surratt et al, 2008;Galloway et al, 2009;De Haan et al, 2011;Yu et al, 2011). Furthermore, atmospheric organic nitrogen plays an essential role in many global processes which may impact the chemistry of the atmosphere as well as climate and biogeochemical cycles.…”

Section: Introductionmentioning

confidence: 99%

Atmospheric water-soluble organic nitrogen (WSON) in the eastern Mediterranean: origin and ramifications regarding marine productivity

Nehir

Koçak

2018

Atmos. Chem. Phys.

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Abstract. Aerosol and rain sampling in two size fractions was carried out at a rural site located on the coast of the eastern Mediterranean, Erdemli, Turkey (36 • 33 54 N, 34 • 15 18 E). A total of 674 aerosol samples in two size fractions (337 coarse, 337 fine) and 23 rain samples were collected between March 2014 and April 2015. Samples were analyzed for NO − 3 , NH + 4 and ancillary water-soluble ions using ion chromatography and water-soluble total nitrogen (WSTN) by applying a high-temperature combustion method. The mean aerosol water-soluble organic nitrogen (WSON) was 23.8 ± 16.3 nmol N m −3 , reaching a maximum of 79 nmol N m −3 , with about 66 % being associated with coarse particles. The volume weighted mean (VWM) concentration of WSON in rain was 21.5 µmol N L −1 . The WSON contributed 37 and 29 % to the WSTN in aerosol and rainwater, respectively. Aerosol WSON concentrations exhibited large temporal variation, mainly due to meteorology and the origin of air mass flow. The highest mean aerosol WSON concentration was observed in the summer and was attributed to the absence of rain and resuspension of cultivated soil in the region. The mean concentration of WSON during dust events (38.2 ± 17.5 nmol N m −3 ) was 1.3 times higher than that of non-dust events (29.4 ± 13.9 nmol N m −3 ). Source apportionment analysis demonstrated that WSON was originated from agricultural activities (43 %), secondary aerosol (20 %), nitrate (22 %), crustal material (10 %) and sea salt (5 %). The dry and wet depositions of WSON were equivalent and amounted to 36 % of the total atmospheric WSTN flux.

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Key parameters controlling OH‐initiated formation of secondary organic aerosol in the aqueous phase (aqSOA)

et al. 2014

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Secondary organic aerosol formation in the aqueous phase of cloud droplets and aerosol particles (aqSOA) might contribute substantially to the total SOA burden and help to explain discrepancies between observed and predicted SOA properties. In order to implement aqSOA formation in models, key processes controlling formation within the multiphase system have to be identified. We explore parameters affecting phase transfer and OH(aq)-initiated aqSOA formation as a function of OH(aq) availability. Box model results suggest OH(aq)-limited photochemical aqSOA formation in cloud water even if aqueous OH(aq) sources are present. This limitation manifests itself as an apparent surface dependence of aqSOA formation. We estimate chemical OH(aq) production fluxes, necessary to establish thermodynamic equilibrium between the phases (based on Henry's law constants) for both cloud and aqueous particles. Estimates show that no (currently known) OH(aq) source in cloud water can remove this limitation, whereas in aerosol water, it might be feasible. Ambient organic mass (oxalate) measurements in stratocumulus clouds as a function of cloud drop surface area and liquid water content exhibit trends similar to model results. These findings support the use of parameterizations of cloud-aqSOA using effective droplet radius rather than liquid water volume or drop surface area. Sensitivity studies suggest that future laboratory studies should explore aqSOA yields in multiphase systems as a function of these parameters and at atmospherically relevant OH(aq) levels. Since aerosol-aqSOA formation significantly depends on OH(aq) availability, parameterizations might be less straightforward, and oxidant (OH) sources within aerosol water emerge as one of the major uncertainties in aerosol-aqSOA formation.

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Glyoxal in Aqueous Ammonium Sulfate Solutions: Products, Kinetics and Hydration Effects

Cited by 229 publications

References 36 publications

Evidence for pyrazine-based chromophores in cloudwater mimics containing methylglyoxal and ammonium sulfate

Evidence for pyrazine-based chromophores in cloudwater mimics containing methylglyoxal and ammonium sulfate

Atmospheric water-soluble organic nitrogen (WSON) in the eastern Mediterranean: origin and ramifications regarding marine productivity

Key parameters controlling OH‐initiated formation of secondary organic aerosol in the aqueous phase (aqSOA)

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