Fast airborne aerosol size and chemistry measurements above Mexico City and Central Mexico during the MILAGRO campaign

DeCarlo, P. F.; Dunlea, E. J.; Kimmel, Joel R.; Aiken, A. C.; Sueper, D.; Crounse, J. D.; Wennberg, P. O.; Emmons, L. K.; Shinozuka, Y.; Clarke, A. D.; Zhou, Jingchuan; Tomlinson, Jason; Collins, D. R.; Knapp, D. J.; Weinheimer, A. J.; Montzka, D. D.; Campos, T.; Jimenez, J. L.

doi:10.5194/acp-8-4027-2008

Cited by 434 publications

(508 citation statements)

References 92 publications

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“…An intermediate slope of −1 is produced by the simultaneous addition of both functional groups, forming a hydroxycarbonyl or carboxylic acid. Organic atmospheric functionalization reactions, including, but not limited to those shown here, generally involve changes not only to O:C but also to H:C. While increasing O:C is often considered an indicator of atmospheric oxidation [e.g., DeCarlo et al, 2008], Figure 1 shows that a non-oxidative process such as hydration reactions can be misinterpreted based on this limited description.…”

Section: Van Krevelen Diagrammentioning

confidence: 91%

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A simplified description of the evolution of organic aerosol composition in the atmosphere

Heald

Kroll

Jimenez

et al. 2010

Geophysical Research Letters

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528

588

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Organic aerosol (OA) in the atmosphere consists of a multitude of organic species which are either directly emitted or the products of a variety of chemical reactions. This complexity challenges our ability to explicitly characterize the chemical composition of these particles. We find that the bulk composition of OA from a variety of environments (laboratory and field) occupies a narrow range in the space of a Van Krevelen diagram (H:C versus O:C), characterized by a slope of ∼−1. The data show that atmospheric aging, involving processes such as volatilization, oxidation, mixing of air masses or condensation of further products, is consistent with movement along this line, producing a more oxidized aerosol. This finding has implications for our understanding of the evolution of atmospheric OA and representation of these processes in models.

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Section: Van Krevelen Diagrammentioning

confidence: 91%

“…[6] Figure [Aiken et al, 2008;DeCarlo et al, 2008]. Also shown is the elemental composition of the individual Positive Matrix Factorization factors during MILAGRO.…”

Section: Application Of the Van Krevelen Diagram To Atmospheric Aerosolmentioning

confidence: 99%

A simplified description of the evolution of organic aerosol composition in the atmosphere

Heald

Kroll

Jimenez

et al. 2010

Geophysical Research Letters

Self Cite

528

588

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“…Figure 1A summarizes observed ∆OA/∆CO enhancement ratios from different studies that were influenced by urban emissions. Red lines are estimates of emission ratios (POA) (7,12,13,(22)(23)(24)(25); blue lines were obtained in aged air (POA + SOA) (7,9,(17)(18)(19)22). These results were determined from field studies on three continents and indicate that the ∆OA/∆CO ratios in aged urban air are systematically higher.…”

Section: Urban Sourcesmentioning

confidence: 96%

“…Figure 1B summarizes ∆OA/∆CO emission ratios (36), as well as enhancement ratios observed in aged biomass burning plumes (9,37,38). There is a large overlap between the two groups, which does not permit strong conclusions about net SOA formation in biomass burning plumes to be drawn at present.…”

Section: Biomass Burning Sourcesmentioning

confidence: 99%

Organic Aerosols in the Earth’s Atmosphere

Gouw

Jimenez²

2009

Environ. Sci. Technol.

397

303

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Organic particles are abundant in the troposphere and important for air quality and climate, but what are their sources?Aerosols, microscopically small particles suspended in air, are an important species in the Earth's atmosphere and influence both air quality and climate. Aerosols are small enough to penetrate deep into the lungs of people and have been linked to severe short-and long-term health effects such as asthma, cardio-respiratory disease, and lung cancer. Aerosols impact the Earth's climate directly through the scattering and absorption of solar radiation, and indirectly through their role as cloud-condensation nuclei. A large fraction (∼50%) of the submicron aerosol mass in the troposphere consists of organic material (1, 2). Direct emissions of organic aerosol (primary organic aerosol or POA) are distinguished from secondary organic aerosol (SOA) formed in the atmosphere from gas-phase precursors. Both POA and the precursors of SOA can be from urban, biogenic, and biomass burning sources. Our understanding of each of these sources is limited at present (3, 4), which hinders the efforts to mitigate the adverse effects. In this feature article, we briefly review the latest insights from field studies into the sources of organic aerosol (OA). Many results were obtained using two relatively new methods for quantifying OA on time scales of minutes: particle-into-liquid sampling combined with total organic carbon analysis for measurements of water-soluble organic carbon (5) and aerosol mass spectrometry (AMS) (6); both have been evaluated in detail against other reported methods, both in terms of the mass loading (7-10) as well as the source apportionment (11-13) of organic aerosol. Urban SourcesGlobal models predict that urban sources of OA are small compared with biomass burning emissions and biogenic SOA formation (4). Nevertheless, several recent studies found that OA was well correlated with tracers of urban pollution such as CO, acetylene (C 2 H 2 ), iso-propylnitrate, and odd oxygen (O 3 + NO 2 ) (8,(14)(15)(16)(17), suggesting that the influence of urban emissions may be larger than previously recognized. These studies showed that the good correlation is not due to emissions of POA, but to a rapid growth of SOA in urban air that overwhelms the direct POA emissions within a few hours of photochemical processing (8,(18)(19)(20).The atmospheric variability in OA is due to the spatial distribution of emissions, transport, chemical transformation, and removal by deposition. By normalizing OA to an inert combustion tracer such as CO or acetylene, the variability due to emissions and transport can be accounted for to a certain extent (8). Enhancement ratios of OA versus CO are denoted as ∆OA/∆CO, where ∆ indicates the excess amount over the background concentration. Accounting for backgrounds is important particularly when using a long-lived species such as CO. In practice, enhancement ratios are often calculated from correlation slopes between OA and CO (7). CO can also be formed from biogenic volatile ...

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“…During MILAGRO, a much wider range of instruments at ground sites, on aircrafts, and satellites was used; the urban "supersite" T0 was located north of the city (see Figure 1). During these studies, a large amount of information regarding the PM in the MCMA was collected in real-time with high resolution, using Aerodyne Aerosol Mass Spectrometers (AMSs) [12][13][14][15][16][17][18]. A more recent similar study was published by Guerrero et al [19] describing the PM 1 chemical composition in a site near T0 (Laboratorio de Análisis Ambiental, LAA) during the 2013-2014 winter/spring season, using an Aerodyne Aerosol Chemical Speciation Monitor (ACSM) [20].…”

Section: Introductionmentioning

confidence: 99%

PM1 Chemical Characterization during the ACU15 Campaign, South of Mexico City

et al. 2018

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Abstract:The "Aerosoles en Ciudad Universitaria 2015" (ACU15) campaign was an intensive experiment measuring chemical and optical properties of aerosols in the winter of 2015, from 19 January to 19 March on a site in the south of Mexico City. The mass concentration and chemical composition of the non-refractory submicron particulate matter (NR-PM 1 ) was determined using an Aerodyne Aerosol Chemical Speciation Monitor (ACSM). The total NR-PM 1 mass concentration measured was lower than reported in previous campaigns that took place north and east of the city. This difference might be explained by the natural variability of the atmospheric conditions, as well as the different sources impacting each site. However, the composition of the aerosol indicates that the aerosol is more aged (a larger fraction of the mass corresponds to sulfate and to low-volatility organic aerosol (LV-OOA)) in the south than the north and east areas; this is consistent with the location of the sources of PM and their precursors in the city, as well as the meteorological patterns usually observed in the metropolitan area.

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Fast airborne aerosol size and chemistry measurements above Mexico City and Central Mexico during the MILAGRO campaign

Cited by 434 publications

References 92 publications

A simplified description of the evolution of organic aerosol composition in the atmosphere

A simplified description of the evolution of organic aerosol composition in the atmosphere

Organic Aerosols in the Earth’s Atmosphere

PM1 Chemical Characterization during the ACU15 Campaign, South of Mexico City

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