Relative contributions of fossil and contemporary carbon sources to PM 2.5 aerosols at nine Interagency Monitoring for Protection of Visual Environments (IMPROVE) network sites

Bench, Graham; Fallon, Stewart; Schichtel, B. A.; Malm, William J; McDade, Charles E.

doi:10.1029/2006jd007708

Cited by 65 publications

(83 citation statements)

References 25 publications

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“…tracers for anthropogenic emissions, such as acetylene, but that budgets of organic aerosol production are poorly represented by current understanding based on yields for individual VOCs measured in smog chambers (de Gouw et al, 2005Quinn et al, 2006;Sullivan et al, 2006). The contribution of biogenic VOCs to organic aerosol production remains uncertain, although recent analysis of radiocarbon in organic aerosol has suggested that a large fraction comes from biogenic sources, even in areas with large anthropogenic VOC emissions (Bench et al, 2007;Schichtel et al, 2008;Weber et al, 2007). Because the yield of SOA from the NO 3 +isoprene reaction (Ng et al, 2008) is some 5-8× larger than from photochemical isoprene oxidation (Kroll et al, 2005), its nighttime oxidation is a mechanism by which biogenic VOCs can more efficiently form SOA in polluted air masses.…”

Section: Secondary Organic Aerosolmentioning

confidence: 99%

“…The reaction is known to produce unsaturated organic nitrates with a yield of approximately 80% as first-generation products (Barnes et al, 1990). These nitrates consist of unsaturated hydroxy-, hydroperoxy-and carbonyl nitrates (Kwok et al, 1996;Skov et al, 1992Skov et al, , 1994Tuazon et al, 1999;Berndt and Boge, 1997), with a recent study also showing evidence for formation of dinitrates and oligomers (Ng et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

“…Because N 2 O 5 hydrolysis is unimportant in comparison to the reaction of NO 3 with isoprene for large isoprene levels, the rate of NO 2 consumption, which is explicitly incorporated into the expression below, is equal to the rate of reaction (R2) (rather than being twice this rate, as would be the case if N 2 O 5 hydrolysis were dominant, . However, the NO 3 +isoprene reaction regenerates a fraction of NO 2 with a yield, NO 2 , of 20%; the remainder of the nitrogen goes to organic nitrates (Barnes et al, 1990).…”

Section: Isoprene Oxidized After Darkmentioning

confidence: 99%

“…Figure 8 shows a time series of different components of reactive nitrogen, including HNO 3 , PAN (shown here as the sum of speciated PANs measured with a chemical ionization mass spectrometer, see Table 1), NO x , N 2 O 5 and isoprene nitrates from isoprene+NO 3 . The isoprene nitrate trace is the product of the estimate for total isoprene reacted after dark and the laboratory organic nitrate yield of 80% (Barnes et al, 1990) and includes only production of these nitrates. Potential loss of these nitrates due to further reaction with NO 3 or with O 3 could reduce the amount of reactive nitrogen stored in this form if it were to result in release of NO 2 from the nitrate, or increase the amount of organic nitrate if, for example, further reaction with NO 3 were to result in the production of di-nitrates.…”

Section: Reactive Nitrogen Partitioningmentioning

confidence: 99%

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Nocturnal isoprene oxidation over the Northeast United States in summer and its impact on reactive nitrogen partitioning and secondary organic aerosol

et al. 2009

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Abstract. Isoprene is the largest single VOC emission to the atmosphere. Although it is primarily oxidized photochemically during daylight hours, late-day emissions that remain in the atmosphere at sunset undergo oxidation by NO 3 in regionally polluted areas with large NO x levels. A recent aircraft study examined isoprene and its nocturnal oxidants in a series of night flights across the Northeast US, a region with large emissions of both isoprene and NO x . Substantial amounts of isoprene that were observed after dark were strongly anticorrelated with measured NO 3 and were the most important factor determining the lifetime of this radical. The products of photochemical oxidation of isoprene, methyl vinyl ketone and methacrolein, were more uniformly distributed, and served as tracers for the presence of isoprene at sunset, prior to its oxidation by NO 3 . A determination of the mass of isoprene oxidized in darkness showed it to be a large fraction (>20%) of emitted isoprene. Organic nitrates produced from the NO 3 +isoprene reaction, though not directly measured, were estimated to account for 2-9% of total reactive nitrogen. The mass of isoprene oxidized by NO 3 was comparable to and correlated with the organic aerosol Correspondence to: S. S. Brown (steven.s.brown@noaa.gov) loading for flights with relatively low organic aerosol background. The contribution of nocturnal isoprene oxidation to secondary organic aerosol was determined in the range 1-17%, and isoprene SOA mass derived from NO 3 was calculated to exceed that due to OH by approximately 50%.

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Section: Secondary Organic Aerosolmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Isoprene Oxidized After Darkmentioning

confidence: 99%

Section: Reactive Nitrogen Partitioningmentioning

confidence: 99%

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Nocturnal isoprene oxidation over the Northeast United States in summer and its impact on reactive nitrogen partitioning and secondary organic aerosol

et al. 2009

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“…(e.g., Georgia), whereas the maxima sulfate and nitrate occur much further north (e.g., Ohio) based on rural IMPROVE network and urban Speciation Trends Network (STN) surface observations (19). The organic aerosol in the SE U.S. is mostly secondary, with radiocarbon ( 14 C) measurements indicating 70% or more of the carbon is modern (rather than fossil) in rural locations and therefore likely of biogenic origin (35,36).…”

Section: Evidence Of Aerosol Chemical Composition In the Eastern Usmentioning

confidence: 99%

Biogenic carbon and anthropogenic pollutants combine to form a cooling haze over the southeastern United States

Goldstein

Koven

Heald

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

314

305

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Remote sensing data over North America document the ubiquity of secondary aerosols resulting from a combination of primary biogenic and anthropogenic emissions. The spatial and temporal distribution of aerosol optical thickness (AOT) over the southeastern United States cannot be explained by anthropogenic aerosols alone, but is consistent with the spatial distribution, seasonal distribution, and temperature dependence of natural biogenic volatile organic compound (BVOC) emissions. These patterns, together with observations of organic aerosol in this region being dominated by modern 14 C and BVOC oxidation products with summer maxima, indicate nonfossil fuel origins and strongly suggest that the dominant summer AOT signal is caused by secondary aerosol formed from BVOC oxidation. A link between anthropogenic and biogenic emissions forming secondary aerosols that dominate the regional AOT is supported by reports of chemicals in aerosols formed by BVOC oxidation in a NO x-and sulfate-rich environment. Even though ground-based measurements from the IMPROVE network suggest higher sulfate than organic concentrations near the surface in this region, we infer that much of the secondary organic aerosol in the Southeast must occur above the surface layer, consistent with reported observations of the organic fraction of the total aerosol increasing with height and models of the expected vertical distribution of secondary organic aerosols from isoprene oxidation. The observed AOT is large enough in summer to provide regional cooling; thus we conclude that this secondary aerosol source is climatically relevant with significant potential for a regional negative climate feedback as BVOC emissions increase with temperature.aerosol ͉ biogenic volatile organic compound ͉ climate ͉ remote sensing ͉ secondary organic aerosols T he importance of biogenic volatile organic compounds (BVOC) reacting with anthropogenic oxides of nitrogen (NO x ) to cause high regional ozone concentrations during summer in the southeastern United States (SE U.S.) was first explained by Chameides et al. (1). This work fundamentally changed the understanding of regulatory approaches for controlling ozone pollution by focusing attention on the need to reduce NO x emissions. We present evidence that similar interactions control secondary aerosol in this region in summer, when concentrations are highest, suggesting that appropriate control strategies focused on the key anthropogenic factors will be required if effects on climate and visibility are to be reduced.The largest uncertainties in projections of radiative forcing involve the direct effects of aerosols on the Earth's radiation budget and the indirect effects through its influence on clouds (2). Atmospheric aerosols come from a combination of anthropogenic and natural sources and include both primary aerosols emitted directly to the atmosphere and secondary aerosols condensing from gaseous precursors. Aerosols above industrialized countries, such as the United States, until recently were generally assu...

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Spatial and seasonal patterns in urban influence on regional concentrations of speciated aerosols across the United States

et al. 2014

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Monthly, seasonal, and annual mean estimates of urban influence on regional concentrations of major aerosol species were computed using speciated aerosol data from the rural IMPROVE network (Interagency Monitoring of Protected Visual Environments) and the United States Environmental Protection Agency's urban Chemical Speciation Network for the 2008 through 2011 period. Aggregated for sites across the continental United States, the annual mean and one standard error in urban excess (defined as the ratio of urban to nearby rural concentrations) was highest for elemental carbon (3.3 ± 0.2), followed by ammonium nitrate (2.5 ± 0.2), particulate organic matter (1.78 ± 0.08), and ammonium sulfate (1.23 ± 0.03). The seasonal variability in urban excess was significant for carbonaceous aerosols and ammonium nitrate in the West, in contrast to the low seasonal variability in the urban influence of ammonium sulfate. Generally for all species, higher excess values in the West were associated with localized urban sources while in the East excess was more regional in extent. In addition, higher excess values in the western United States in winter were likely influenced not only by differences in sources but also by combined meteorological and topographic effects. This work has implications for understanding the spatial heterogeneity of major aerosol species near the interface of urban and rural regions and therefore for designing appropriate air quality management strategies. In addition, the spatial patterns in speciated mass concentrations provide constraints for regional and global models.

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Relative contributions of fossil and contemporary carbon sources to PM 2.5 aerosols at nine Interagency Monitoring for Protection of Visual Environments (IMPROVE) network sites

Cited by 65 publications

References 25 publications

Nocturnal isoprene oxidation over the Northeast United States in summer and its impact on reactive nitrogen partitioning and secondary organic aerosol

Nocturnal isoprene oxidation over the Northeast United States in summer and its impact on reactive nitrogen partitioning and secondary organic aerosol

Biogenic carbon and anthropogenic pollutants combine to form a cooling haze over the southeastern United States

Spatial and seasonal patterns in urban influence on regional concentrations of speciated aerosols across the United States

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