Competing Photochemical Effects in Aqueous Carbonyl/Ammonium Brown Carbon Systems

Sharp, Jacqueline R.; Grace, Daisy N.; Ma, Shiqing; Woo, Joseph L.; Galloway, Melissa M.

doi:10.1021/acsearthspacechem.1c00165

Cited by 9 publications

(13 citation statements)

References 45 publications

(203 reference statements)

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“…3, 4, and 5 in Table 1) because IM is the most abundant species in the reaction of reduced nitrogen species with glyoxal. 13,17,21 IM concentration was found to be 1 and 3 orders of magnitude higher than IC and BI concentration, respectively. 13,17 Sharp et al 21 found that mass abundance of IM decreased, whereas IC disappeared after irradiation with broadband wavelength.…”

Section: ■ Materials and Methodsmentioning

confidence: 81%

Photochemical Reactions of Glyoxal during Particulate Ammonium Nitrate Photolysis: Brown Carbon Formation, Enhanced Glyoxal Decay, and Organic Phase Formation

Zhang

Gen

Liang

et al. 2022

Environ. Sci. Technol.

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Glyoxal is an important precursor of aqueous secondary organic aerosol (aqSOA). Its photooxidation to form organic acids and oligomers and reactions with reduced nitrogen compounds to form brown carbon (BrC) have been extensively investigated separately, although these two types of reactions can occur simultaneously during the daytime. Here, we examine the reactions of glyoxal during photooxidation and BrC formation in premixed NH 4 NO 3 + Glyoxal droplets. We find that nitrate photolysis and photosensitization can enhance the decay rates of glyoxal by a factor of ∼5 and ∼6 compared to those under dark, respectively. A significantly enhanced glyoxal decay rate by a factor of ∼12 was observed in the presence of both nitrate photolysis and photosensitization. Furthermore, a new organic phase was formed in irradiated NH 4 NO 3 + Glyoxal droplets, which had no noticeable degradation under prolonged photooxidation. It was attributed to the imidazole oxidation mediated by nitrate photolysis and/or photosensitization. The persistent organic phase suggests the potential to contribute to SOA formation in ambient fine particles. This study highlights that glyoxal photooxidation mediated by nitrate photolysis and photosensitization can significantly enhance the atmospheric sink of glyoxal, which may partially narrow the gap between model predictions and field measurements of ambient glyoxal concentrations.

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Section: ■ Materials and Methodsmentioning

confidence: 81%

Photochemical Reactions of Glyoxal during Particulate Ammonium Nitrate Photolysis: Brown Carbon Formation, Enhanced Glyoxal Decay, and Organic Phase Formation

Zhang

Gen

Liang

et al. 2022

Environ. Sci. Technol.

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“…Recent work suggests that the source of the climate-warming effect of BrC, its absorption of solar radiation, may also be a significant loss process for BrC. Photodegradation/photobleaching of BrC, for some select cases, has been shown to be significant, resulting in atmospheric lifetimes that may be hours or less. ,− However, the nuances of this photochemical aging for ambient-derived BrC make the prevalence of photobleaching more case-specific, rather than a completely general effect. BrC from methylglyoxal in ammonium sulfate solution was shown to quickly bleach upon irradiation, declining by over 75% within an hour, briefly increase in absorption, and then slowly decline over a period of 24 h .…”

Section: Atmospheric Implicationsmentioning

confidence: 99%

“…Photodegradation/photobleaching of BrC, for some select cases, has been shown to be significant, resulting in atmospheric lifetimes that may be hours or less. ,− However, the nuances of this photochemical aging for ambient-derived BrC make the prevalence of photobleaching more case-specific, rather than a completely general effect. BrC from methylglyoxal in ammonium sulfate solution was shown to quickly bleach upon irradiation, declining by over 75% within an hour, briefly increase in absorption, and then slowly decline over a period of 24 h . Larger BrC compounds, identified by higher molecular weight, appear to be more resistant to photobleaching; mixtures of many BrC chromophores can lead to photochemical lifetimes orders of magnitude longer than the individual components. , In this work, we focus on the formation aspect of BrC levels, showing that bulk aerosol composition, accounting for both inorganic and organic content, makes the rate of BrC formation quite variable.…”

Section: Atmospheric Implicationsmentioning

confidence: 99%

Effects of Organic Matrices on Nucleophilic Aqueous Aerosol Chemistry: Yields and Mechanistic Insight for Brown Carbon Formation from Glyoxal and Ammonia

Drozd

Brown

Karp

2022

ACS Earth Space Chem.

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Climate forcing effects of tropospheric aerosols are determined by their relative abilities to absorb and scatter light and also their effects on cloud properties and lifetime, which may lead to net warming or cooling of the atmosphere. Many details of the formation and lifecycle of organic content that contributes to aerosol light absorption, termed brown carbon (BrC), remain uncertain after extensive study. The reactive species that form BrC make up only a small fraction of total aerosol organic content, and the overwhelming remainder of organic content could greatly influence the rate of BrC formation. One significant route to BrC formation is the reaction of water-soluble carbonyl species to form larger conjugated and/or aromatic compounds, such as the reaction of di-aldehydes (e.g., glyoxal) with reduced nitrogen species (ammonia or amines) to form imidazole derivatives. In this study, we work to further address the complexity of atmospheric aerosols by adding a matrix of organic content to the glyoxal–ammonium system. We find that the addition of a broad range of organic species (alcohols, ketones, organic acids, etc.) to BrC-forming reaction mixtures can both increase and decrease the rate of BrC formation. The rate of BrC formation is shown to vary by more than an order of magnitude depending on the composition of the organic matrix present. UV–vis kinetic measurements and HPLC-ToF-MS product analysis of aqueous solutions with qualities similar to atmospheric aerosols reveal the specific steps in BrC formation affected by the presence of organic content. Our method of systematically adding complexity also proves a useful tool for mechanistic evaluation, and we provide evidence that the proposed cis-di-imine mechanism for the reaction of ammonia and glyoxal is unlikely, with amine species reacting instead.

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“…In this virtual special issue, the aqueous oxidation of the isoprene oxidation product 2-methyltetrol was shown to be a potentially significant source of formic and acetic acids in the atmosphere . The photochemical processing of light-absorbing organic aerosol material or “brown carbon” is another potential source of VOCs, with implications for Earth’s radiative balance. , The formation of secondary organic aerosol (SOA) from the chlorine oxidation of α-pinene was characterized, and SOA material formed from α-pinene and d -limonene was shown to be relatively stable when exposed to gas- or liquid-phase water . The heterogeneous chemistry of oleic acid aerosol, a very well-studied system, was re-examined using an inverse multiphase modeling approach, revealing new mechanistic details …”

Section: Fundamentals Of Atmospheric Chemistrymentioning

confidence: 99%

Mario Molina Memorial Special Issue

McNeill

2022

ACS Earth Space Chem.

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Competing Photochemical Effects in Aqueous Carbonyl/Ammonium Brown Carbon Systems

Cited by 9 publications

References 45 publications

Photochemical Reactions of Glyoxal during Particulate Ammonium Nitrate Photolysis: Brown Carbon Formation, Enhanced Glyoxal Decay, and Organic Phase Formation

Photochemical Reactions of Glyoxal during Particulate Ammonium Nitrate Photolysis: Brown Carbon Formation, Enhanced Glyoxal Decay, and Organic Phase Formation

Effects of Organic Matrices on Nucleophilic Aqueous Aerosol Chemistry: Yields and Mechanistic Insight for Brown Carbon Formation from Glyoxal and Ammonia

Mario Molina Memorial Special Issue

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