Uncertainties in Modeling Secondary Organic Aerosols:  Three-Dimensional Modeling Studies in Nashville/Western Tennessee

Pun, Betty K.; Wu, S. C.; Seigneur, Christian; Seinfeld, John H.; Griffin, Robert J.; Pandis, Spyros Ν.

doi:10.1021/es0341541

Cited by 118 publications

(129 citation statements)

References 30 publications

(22 reference statements)

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“…On one hand, one can treat the atmospheric particles as internal mixtures (all particles of a same size have the same chemical composition) and solve he thermodynamics with possible phase separation (e.g., mostly organic and aqueous phases) as performed by Pun (2008) and Zuend et al (2010). On the other hand, one can treat the atmospheric particles as external mixtures with aqueous (mostly inorganic) particles being distinct from hydrophobic (mostly organic) particles as performed by Pun et al (2002Pun et al ( , 2006. The latter approach is used here.…”

Section: Extension Of the Model To Humid Conditionsmentioning

confidence: 99%

“…The condensation of SOA on the organic phase under high-NO x conditions is then due to the hydrophobic properties of BiNGA (only a small quantity of C 5 -hydroxy-trinitrate is formed under the conditions considered here). The AER/EPRI/Caltech model (AEC) (Pun et al, 2002(Pun et al, , 2003(Pun et al, , 2006) is a model for SOA formation that takes into account the hydrophilic and hydrophobic properties of surrogates. It distinguishes compounds into two types: hydrophilic compounds (which are absorbed only in an aqueous particle) and hydrophobic compounds (which are absorbed only in an organic particle).…”

Section: Influence Of An Aqueous Phase On Soa Formationmentioning

confidence: 99%

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Modeling secondary organic aerosol formation from isoprene oxidation under dry and humid conditions

Couvidat

Seigneur

2011

Atmos. Chem. Phys.

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Abstract.A new model for the formation of secondary organic aerosol (SOA) from isoprene was developed. This model uses surrogate molecular species (hydroxyhydroperoxides, tetrols, methylglyceric acid, organic nitrates) to represent SOA formation. The development of this model used available experimental data on yields and molecular composition of SOA from isoprene and methacrolein oxidation. This model reproduces the amount of particles measured in smog chambers under both low-NO x and high-NO x conditions. Under low-NO x conditions, the model reproduces the transitional formation of hydroxy-hydroperoxides particles, which are photolyzed and lead to SOA mass decrease after reaching a maximum. Under high-NO x conditions, particles are assumed to be formed mostly from the photo-oxidation of a PAN-type molecule derived from methacrolein (MPAN). This model successfully reproduces the complex NO x -dependence of isoprene oxidation and suggests a possible yield increase under some high-NO x conditions. Experimental data correspond to dry conditions (RH < 10%). However, particles formed from isoprene are expected to be highly hydrophilic, and isoprene oxidation products would likely partition between an aqueous phase and the gas phase at high humidity in the atmosphere. The model was extended to take into account the hydrophilic properties of SOA, which are relevant under atmospheric conditions, and investigate the effect of particulate liquid water on SOA formation. An important increase in SOA mass was estimated for humid conditions due to the hydrophilic properties. Experiments under high relative humidity conditions should be conducted to confirm the results of this study, which have implications for SOA modeling.

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Section: Extension Of the Model To Humid Conditionsmentioning

confidence: 99%

Section: Influence Of An Aqueous Phase On Soa Formationmentioning

confidence: 99%

Modeling secondary organic aerosol formation from isoprene oxidation under dry and humid conditions

Couvidat

Seigneur

2011

Atmos. Chem. Phys.

View full text Add to dashboard Cite

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“…The additional water uptake can occur in the presence of hydrophilic SOA when the ambient relative humidity (RH) is above the DRH of any individual OC in the particulate phase Hildemann, 1996, 1997). The addition of organic ions changes the pH and total water content of aqueous particles, and consequently, affects the partitioning of inorganic compounds, such as nitrate and ammonium (Saxena et al, 1995;Cruz and Pandis, 2000;Pun et al, 2003). The role of SOA in total aerosol water and in transferring of nitrate into the aerosol phase is significant, especially at low RH (<50%) and high SOA mass fractions (>20% of total PM 2.5 ) (Ansari and Pandis, 2000).…”

Section: Model Descriptionmentioning

confidence: 99%

“…A globallyconvergent Newton/line search method is used to solve the partitioning equations simultaneously. Some simplifications are provided as alternatives to detailed treatments to improve computational efficiency in 3-D applications (Pun et al, 2003). For example, the amount of water associated with hydrophilic OCs is calculated by assuming that the water associated with each hydrophilic compound in a binary solution is additive (i.e., using the ZSR equation).…”

Section: Model Descriptionmentioning

confidence: 99%

“…The speciation of NMHCs for all the initial CACM organic species except biogenic VOCs (i.e., isoprene (ISOP), and monoterpenes (BIOL+BIOH)) is based on the specific distribution factors of Griffin et al (2002a). Following the approach of Griffin et al (2002a) and Pun et al (2003), the same speciation is applied to the entire simulation domain because of lack of data to distinguish speciation in rural and urban areas. The concentrations of isoprene and monoterpenes in the ambient air are typically in the range of 1 to 10 ppbC (Finlayson-Pitts and Pitts, 1986;NTP, 2005).…”

Section: Test Conditions and Model Inputsmentioning

confidence: 99%

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A computationally-efficient secondary organic aerosol module for three-dimensional air quality models

Liu

Zhang

2008

Atmos. Chem. Phys.

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Abstract. Accurately simulating secondary organic aerosols (SOA) in three-dimensional (3-D) air quality models is challenging due to the complexity of the physics and chemistry involved and the high computational demand required. A computationally-efficient yet accurate SOA module is necessary in 3-D applications for long-term simulations and realtime air quality forecasting. A coupled gas and aerosol box model (i.e., 0-D CMAQ-MADRID 2) is used to optimize relevant processes in order to develop such a SOA module. Solving the partitioning equations for condensable volatile organic compounds (VOCs) and calculating their activity coefficients in the multicomponent mixtures are identified to be the most computationally-expensive processes. The two processes can be speeded up by relaxing the error tolerance levels and reducing the maximum number of iterations of the numerical solver for the partitioning equations for organic species; conditionally activating organic-inorganic interactions; and parameterizing the calculation of activity coefficients for organic mixtures in the hydrophilic module. The optimal speed-up method can reduce the total CPU cost by up to a factor of 31.4 from benchmark under the rural conditions with 2 ppb isoprene and by factors of 10-71 under various test conditions with 2-10 ppb isoprene and >40% relative humidity while maintaining ±15% deviation. These speed-up methods are applicable to other SOA modules that are based on partitioning theories.

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Toxicity of Inhaled Nanomaterials

Pickrell¹,

Erickson²,

Dhakal³

et al. 2009

Nanoscale Materials in Chemistry

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Uncertainties in Modeling Secondary Organic Aerosols: Three-Dimensional Modeling Studies in Nashville/Western Tennessee

Cited by 118 publications

References 30 publications

Modeling secondary organic aerosol formation from isoprene oxidation under dry and humid conditions

Modeling secondary organic aerosol formation from isoprene oxidation under dry and humid conditions

A computationally-efficient secondary organic aerosol module for three-dimensional air quality models

Toxicity of Inhaled Nanomaterials

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