Glyoxal uptake on ammonium sulphate seed aerosol: reaction products and reversibility of uptake under dark and irradiated conditions

Galloway, Melissa M.; Chhabra, P. S.; Chan, Arthur W. H.; Surratt, Jason D.; Flagan, Richard C.; Seinfeld, John H.; Keutsch, Frank N.

doi:10.5194/acp-9-3331-2009

Cited by 392 publications

(467 citation statements)

References 58 publications

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“…[21] This suggests that the presence of NH 4 þ at cloud-relevant concentrations will not affect GLY þ OH chemistry. In addition, we found no evidence of the imidazoles reported by Galloway et al [6] by FT-ICR MS in the positive mode.…”

Section: Organic Nitrogencontrasting

confidence: 39%

“…[37] In addition, imidazole formation has been detected in (dark) concentrated aldehydeammonium sulfate solutions and chamber experiments. [6,34] Inorganic and organic concentrations are orders of magnitude smaller in clouds and fogs. Although experiments have been performed to examine the effect of dilute (cloud-relevant) concentrations of acidic sulfate on GLY chemistry, [33] to our knowledge the degree to which GLY þ OH chemistry is altered by the presence of cloud-relevant concentrations of nitrate or ammonium has not been examined.…”

Section: Introductionmentioning

confidence: 99%

“…[32,33] Organic nitrogen and sulfur compounds have been observed to form in highly concentrated aqueous solutions relevant to wet aerosols. [6,[34][35][36][37] Evidence for the photochemical formation of organosulfates from GLY and other aldehydes is provided through studies of bulk sulfate solutions and through smog chamber experiments with ammonium sulfate seed particles and UV irradiation. [6,35,36] Aerosol mimic solutions containing GLY and inorganic ammonium salts have yielded products with carbon-nitrogen bonds in the absence of major atmospheric oxidants (i.e.…”

Section: Introductionmentioning

confidence: 99%

“…oxalate, glycolate, oligomers, epoxide sulfates and imidazoles). [1][2][3][4][5][6][7][8][9][10][11] As a result, gas-phase followed by aqueous-phase chemistry contributes to secondary organic aerosol (SOA). [12,13] SOA is also formed when semiand low-volatility products of gas-phase chemistry sorb to particulate organic matter [14,15] (here SOA gas is used to denote SOA formed by this latter pathway and SOA aq to denote SOA formed with a contribution from aqueous-phase chemistry).…”

Section: Introductionmentioning

confidence: 99%

“…oxalate, oligomers, organosulfate and imidazole). [6,8,[32][33][34] Because these compounds are found predominantly in the condensed phase in the atmosphere, aqueous reaction of GLY contributes to SOA aq . [32,33] Organic nitrogen and sulfur compounds have been observed to form in highly concentrated aqueous solutions relevant to wet aerosols.…”

Section: Introductionmentioning

confidence: 99%

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Glyoxal secondary organic aerosol chemistry: effects of dilute nitrate and ammonium and support for organic radical–radical oligomer formation

Kirkland¹,

Lim²,

Tan³

et al. 2013

Environ. Chem.

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Environmental context. Atmospheric waters (clouds, fogs and wet aerosols) are media in which gases can be converted into particulate matter. This work explores aqueous transformations of glyoxal, a water-soluble gas with anthropogenic and biogenic sources. Results provide new evidence in support of previously proposed chemical mechanisms. These mechanisms are beginning to be incorporated into transport models that link emissions to air pollution concentrations and behaviour.Abstract. Glyoxal (GLY) is ubiquitous in the atmosphere and an important aqueous secondary organic aerosol (SOA) precursor. At dilute (cloud-relevant) organic concentrations, OH radical oxidation of GLY has been shown to produce oxalate. GLY has also been used as a surrogate species to gain insight into radical and non-radical reactions in wet aerosols, where organic and inorganic concentrations are very high (in the molar region). The work herein demonstrates, for the first time, that tartarate forms from GLY þ OH . Tartarate is a key product in a previously proposed organic radical-radical reaction mechanism for oligomer formation from GLY oxidation. Previously published model predictions that include this GLY oxidation pathway suggest that oligomers are major products of OH radical oxidation at the high organic concentrations found in wet aerosols. The tartarate measurements herein provide support for this proposed oligomer formation mechanism. This paper also demonstrates, for the first time, that dilute (cloud or fog-relevant) concentrations of inorganic nitrogen (i.e. ammonium and nitrate) have little effect on the GLY þ OH chemistry leading to oxalate formation in clouds. This, and results from previous experiments conducted with acidic sulfate, increase confidence that the currently understood dilute GLY þ OH chemistry can be used to predict GLY SOA formation in clouds and fogs. It should be recognised that organic-inorganic interactions can play an important role in droplet evaporation chemistry and in wet aerosols. The chemistry leading to SOA formation in these environments is complex and remains poorly understood.

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Section: Organic Nitrogencontrasting

confidence: 39%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Glyoxal secondary organic aerosol chemistry: effects of dilute nitrate and ammonium and support for organic radical–radical oligomer formation

Kirkland¹,

Lim²,

Tan³

et al. 2013

Environ. Chem.

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Reconciling modeled and observed atmospheric deposition of soluble organic nitrogen at coastal locations

Ito

Lin

Penner

2014

Global Biogeochemical Cycles

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Atmospheric deposition of reactive nitrogen (N) species from air pollutants is a significant source of exogenous nitrogen in marine ecosystems. Here we use an atmospheric chemical transport model to investigate the supply of soluble organic nitrogen (ON) from anthropogenic sources to the ocean. Comparisons of modeled deposition with observations at coastal and marine locations show good overall agreement for inorganic nitrogen and total soluble nitrogen. However, previous modeling approaches result in significant underestimates of the soluble ON deposition if the model only includes the primary soluble ON and the secondary oxidized ON in gases and aerosols. Our model results suggest that including the secondary reduced ON in aerosols as a source of soluble ON contributes to an improved prediction of the deposition rates (g N m À2 yr À1). The model results show a clear distinction in the vertical distribution of soluble ON in aerosols between different processes from the primary sources and the secondary formation. The model results (excluding the biomass burning and natural emission changes) suggest an increase in soluble ON outflow from atmospheric pollution, in particular from East Asia, to the oceans in the twentieth century. These results highlight the necessity of improving the process-based quantitative understanding of the chemical reactions of inorganic nitrogen species with organics in aerosol and cloud water.

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Radiative forcing of organic aerosol in the atmosphere and on snow: Effects of SOA and brown carbon

Lin

Penner

Flanner

et al. 2014

J. Geophys. Res. Atmos.

233

236

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Organic aerosols (OA) play an important role in climate change. However, very few calculations of global OA radiative forcing include secondary organic aerosol (SOA) or the light-absorbing part of OA (brown carbon). Here we use a global model to assess the radiative forcing associated with the change in primary organic aerosol (POA) and SOA between present-day and preindustrial conditions in both the atmosphere and the land snow/sea ice. Anthropogenic emissions are shown to substantially influence the SOA formation rate, causing it to increase by 29 Tg/yr (93%) since preindustrial times. We examine the effects of varying the refractive indices, size distributions for POA and SOA, and brown carbon fraction in SOA. The increase of SOA exerts a direct forcing ranging from À0.12 to À0.31 W m À2 and a first indirect forcing in warm-phase clouds ranging from À0.22 to À0.29 W m À2, with the range due to different assumed SOA size distributions and refractive indices. The increase of POA since preindustrial times causes a direct forcing varying from À0.06 to À0.11 W m À2, when strongly and weakly absorbing refractive indices for brown carbon are used. The change in the total OA exerts a direct forcing ranging from À0.14 to À0.40 W m À2 . The atmospheric absorption from brown carbon ranges from +0.22 to +0.57 W m À2 , which corresponds to 27%~70% of the black carbon (BC) absorption predicted in the model. The radiative forcing of OA deposited in land snow and sea ice ranges from +0.0011 to +0.0031 W m À2 or as large as 24% of the forcing caused by BC in snow and ice simulated by the model.

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Glyoxal uptake on ammonium sulphate seed aerosol: reaction products and reversibility of uptake under dark and irradiated conditions

Cited by 392 publications

References 58 publications

Glyoxal secondary organic aerosol chemistry: effects of dilute nitrate and ammonium and support for organic radical–radical oligomer formation

Glyoxal secondary organic aerosol chemistry: effects of dilute nitrate and ammonium and support for organic radical–radical oligomer formation

Reconciling modeled and observed atmospheric deposition of soluble organic nitrogen at coastal locations

Radiative forcing of organic aerosol in the atmosphere and on snow: Effects of SOA and brown carbon

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