The influence of semi-volatile and reactive primary emissions on the abundance and properties of global organic aerosol

Jathar, Shantanu H.; Farina, S. C.; Robinson, Allen L.; Adams, P. J.

doi:10.5194/acp-11-7727-2011

Cited by 94 publications

(131 citation statements)

References 76 publications

(135 reference statements)

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“…Traditionally, models have tended to predict a predominance of POA over SOA (Chung and Seinfeld, 2002;Kanakidou et al, 2005;Pun et al, 2003;Vutukuru et al, 2006), but measurement studies show striking evidence of SOA dominance observed at various locations, even in heavily urbanized locations (Zhang et al, 2005de Gouw et al, 2005;Volkamer et al, 2006). Recent work has suggested that many global models are underestimating OA sources (Heald et al, 2010;Spracklen et al, 2011b) that appear to be SOA, and recent improvements in SOA modeling efforts have addressed this discrepancy (Jathar et al, 2011;Pye and Seinfeld, 2010). To complicate the matter even further, different measurement techniques result in different SOA/OA fractions, as was the case for the Pittsburgh Air Quality Study, for which SOA/OA values were estimated to be 35-73 % (Subramanian et al, 2007;Cabada et al, 2004;Shrivastava et al, 2007;Zhang et al, 2005).…”

Section: W Trivitayanurak and P J Adams: Does The Poa-soa Split Mamentioning

confidence: 99%

“…Traditional global models that have included SOA produced from "traditional" anthropogenic organic precursors (i.e., single compounds with well-characterized smog chamber yields such as aromatics) have predicted that these make a small contribution (about 10 %) to global OA sources (Tsigaridis and Kanakidou, 2003;Farina et al, 2010), so they are not considered here. Potentially much larger sources of anthropogenic SOA from IVOC oxidation (Jathar et al, 2011;Pye and Seinfeld, 2010) are considered in the sensitivity studies (see Sect. 2.4).…”

Section: Secondary Organic Aerosolmentioning

confidence: 99%

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Does the POA–SOA split matter for global CCN formation?

Trivitayanurak

Adams

2014

Atmos. Chem. Phys.

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Abstract.A model of carbonaceous aerosols has been implemented in the TwO-Moment Aerosol Sectional (TOMAS) microphysics module in the GEOS-Chem chemical transport model (CTM), a model driven by assimilated meteorology. Inclusion of carbonaceous emissions alongside pre-existing treatments of sulfate and sea-salt aerosols increases the number of emitted primary aerosol particles by a factor of 2.5 and raises annual-average global cloud condensation nuclei at 0.2 % supersaturation (CCN(0.2 %)) concentrations by a factor of two. Compared to the prior model without carbonaceous aerosols, this development improves the model prediction of condensation nuclei with dry diameter larger than 10 nm (CN10) number concentrations significantly from −45 % to −7 % bias when compared to long-term observations. Inclusion of carbonaceous particles also largely eliminates a tendency for the model to underpredict higher cloud condensation nuclei (CCN) concentrations. Similar to other carbonaceous models, the model underpredicts organic carbon (OC) and elemental carbon (EC) mass concentrations by a factor of 2 when compared to EMEP and IMPROVE observations. Because primary organic aerosol (POA) and secondary organic aerosol (SOA) affect aerosol number size distributions via different microphysical processes, we assess the sensitivity of CCN production, for a fixed source of organic aerosol (OA) mass, to the assumed POA-SOA split in the model. For a fixed OA budget, we found that CCN(0.2 %) decreases nearly everywhere as the model changes from a world dominated by POA emissions to one dominated by SOA condensation. POA is about twice as effective per unit mass at CCN production compared to SOA. Changing from a 100 % POA scenario to a 100 % SOA scenario, CCN(0.2 %) concentrations in the lowest model layer decrease by about 20 %. In any scenario, carbonaceous aerosols contribute significantly to global CCN. The SOA-POA split has a significant effect on global CCN, and the microphysical implications of POA emissions versus SOA condensation appear to be at least as important as differences in chemical composition as expressed by the hygroscopicity of OA. These findings stress the need to better understand carbonaceous aerosols loadings, the global SOA budget, microphysical pathways of OA formation (emissions versus condensation) as well as chemical composition to improve climate modeling.

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Section: W Trivitayanurak and P J Adams: Does The Poa-soa Split Mamentioning

confidence: 99%

Section: Secondary Organic Aerosolmentioning

confidence: 99%

Does the POA–SOA split matter for global CCN formation?

Trivitayanurak

Adams

2014

Atmos. Chem. Phys.

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“…3370 A. P. : an efficient module to compute volatility and oxygen content approach, semi-volatile primary emissions, chemical aging, and SOA formation were unified within a common framework that is ideally suited for regional and global chemical modeling. Since 2006, many regional (Lane et al, 2008;Murphy and Pandis, 2009;Tsimpidi et al, , 2011Ahmadov et al, 2012;Athanasopoulou et al, 2013;Koo et al, 2014;Fountoukis et al, 2014;Ciarelli et al, 2017;Gao et al, 2017) and global (Pye and Seinfeld, 2010;Jathar et al, 2011;Jo et al, 2013;Tsimpidi et al, 2014;Hodzic et al, 2016) modeling studies have used the VBS to account for the semi-volatile nature and chemical aging of organic compounds, demonstrating improvements in reproducing the OA budget and its chemical resolution.…”

Section: Introductionmentioning

confidence: 99%

ORACLE 2-D (v2.0): an efficient module to compute the volatility and oxygen content of organic aerosol with a global chemistry–climate model

et al. 2018

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Abstract. A new module, ORACLE 2-D, simulating organic aerosol formation and evolution in the atmosphere has been developed and evaluated. The module calculates the concentrations of surrogate organic species in two-dimensional space defined by volatility and oxygen-to-carbon ratio. It is implemented into the EMAC global chemistry-climate model, and a comprehensive evaluation of its performance is conducted using an aerosol mass spectrometer (AMS) factor analysis dataset derived from almost all major field campaigns that took place globally during the period 2001-2010. ORACLE 2-D uses a simple photochemical aging scheme that efficiently simulates the net effects of fragmentation and functionalization of the organic compounds. The module predicts not only the mass concentration of organic aerosol (OA) components, but also their oxidation state (in terms of O : C), which allows for their classification into primary OA (POA, chemically unprocessed), fresh secondary OA (SOA, low oxygen content), and aged SOA (highly oxygenated). The explicit simulation of chemical OA conversion from freshly emitted compounds to a highly oxygenated state during photochemical aging enables the tracking of hygroscopicity changes in OA that result from these reactions. OR-ACLE 2-D can thus compute the ability of OA particles to act as cloud condensation nuclei and serves as a tool to quantify the climatic impact of OA.

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“…This framework describes the OA absorptive partitioning, where OA is assumed to be semivolatile and photochemically reactive and is distributed in logarithmically spaced volatility bins. With this approach, the intermediate and semivolatile primary emissions and the SOA formation and its chemical aging can be simulated in a common framework that is well suited for regional and global modeling (Murphy and Pandis, 2009;Jathar et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

ORACLE (v1.0): module to simulate the organic aerosol composition and evolution in the atmosphere

et al. 2014

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Abstract.A computationally efficient module to describe organic aerosol (OA) partitioning and chemical aging has been developed and implemented into the EMAC atmospheric chemistry-climate model. The model simulates the formation of secondary organic aerosol (SOA) from semivolatile (SVOCs), intermediate-volatility (IVOCs), and volatile organic compounds (VOCs). It distinguishes SVOCs from biomass burning and all other combustion sources using two surrogate species for each source category with an effective saturation concentration at 298 K of C * = 0.1 and 10 µg m −3 . Two additional surrogate species with C * = 10 3 and 10 5 µg m −3 are used for the IVOCs emitted by the above source categories. Gas-phase photochemical reactions that change the volatility of the organics are taken into account. The oxidation products (SOA-sv, SOA-iv, and SOA-v) of each group of precursors (SVOCs, IVOCs, and VOCs) are simulated separately to keep track of their origin. ORACLE efficiently describes the OA composition and evolution in the atmosphere and can be used to (i) estimate the relative contributions of SOA and primary organic aerosol (POA) to total OA, (ii) determine how SOA concentrations are affected by biogenic and anthropogenic emissions, and (iii) evaluate the effects of photochemical aging and long-range transport on the OA budget. We estimate that the global average nearsurface OA concentration is 1.5 µg m −3 and consists of 7 % POA from fuel combustion, 11 % POA from biomass burning, 2 % SOA-sv from fuel combustion, 3 % SOA-sv from biomass burning, 15 % SOA-iv from fuel combustion, 28 % SOA-iv from biomass burning, 19 % biogenic SOA-v, and 15 % anthropogenic SOA-v. The modeled tropospheric burden of OA components is 0.23 Tg POA, 0.16 Tg SOA-sv, 1.41 Tg SOA-iv, and 1.2 Tg SOA-v.

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The influence of semi-volatile and reactive primary emissions on the abundance and properties of global organic aerosol

Cited by 94 publications

References 76 publications

Does the POA–SOA split matter for global CCN formation?

Does the POA–SOA split matter for global CCN formation?

ORACLE 2-D (v2.0): an efficient module to compute the volatility and oxygen content of organic aerosol with a global chemistry–climate model

ORACLE (v1.0): module to simulate the organic aerosol composition and evolution in the atmosphere

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