TY - JOUR
T1 - Real-time measurements of secondary organic aerosol formation and aging from ambient air in an oxidation flow reactor in the Los Angeles area
AU - Ortega, Amber M.
AU - Hayes, Patrick L.
AU - Peng, Zhe
AU - Palm, Brett B.
AU - Hu, Weiwei
AU - Day, Douglas A.
AU - Li, Rui
AU - Cubison, Michael J.
AU - Brune, William H.
AU - Graus, Martin
AU - Warneke, Carsten
AU - Gilman, Jessica B.
AU - Kuster, William C.
AU - De Gouw, Joost
AU - Gutiérrez-Montes, Cándido
AU - Jimenez, Jose L.
N1 - Funding Information:
We thank CARB 08-319 and 11-305, DOE (BER, ASP Program) DE-SC0006035 and DE-SC0011105, NOAA NA13OAR4310063, and NSF AGS-1243354 and AGS-1360834, and EPA STAR 83587701-0 for partial support of this work. EPA has not reviewed this manuscript and thus no endorsement should be inferred. AMO and PLH acknowledge fellowships from the DOE SCGP Fellowship Program (ORAU, ORISE) and the CIRES Visiting Fellowship program, respectively. WHB acknowledges the support by NSF (grant ATM-0919079). We thank Phil Stevens' research group (Indiana University) for use of OH reactivity data from the CalNex Pasadena ground site. We are grateful to Jochen Stutz (UCLA), John Seinfeld (Caltech), and Jason Surratt (UNC-Chapel Hill) for co-organization of the CalNex Supersite, and to CARB for supporting the infrastructure at the site. We also thank John S. Holloway (NOAA) for providing CO data, Roya Bahreini (University of California-Riverside), and Ann M. Middlebrook (NOAA) for providing OA data from the NOAA WP-3D. We thank Carlos Martinez (Univ. Jaen) for useful discussions about CFD modeling of the OFR.
Publisher Copyright:
© Author(s) 2016.
PY - 2016/6/15
Y1 - 2016/6/15
N2 - Field studies in polluted areas over the last decade have observed large formation of secondary organic aerosol (SOA) that is often poorly captured by models. The study of SOA formation using ambient data is often confounded by the effects of advection, vertical mixing, emissions, and variable degrees of photochemical aging. An oxidation flow reactor (OFR) was deployed to study SOA formation in real-time during the California Research at the Nexus of Air Quality and Climate Change (CalNex) campaign in Pasadena, CA, in 2010. A high-resolution aerosol mass spectrometer (AMS) and a scanning mobility particle sizer (SMPS) alternated sampling ambient and reactor-aged air. The reactor produced OH concentrations up to 4 orders of magnitude higher than in ambient air. OH radical concentration was continuously stepped, achieving equivalent atmospheric aging of 0.8 days- 6.4 weeks in 3 min of processing every 2 h. Enhancement of organic aerosol (OA) from aging showed a maximum net SOA production between 0.8-6 days of aging with net OA mass loss beyond 2 weeks. Reactor SOA mass peaked at night, in the absence of ambient photochemistry and correlated with trimethylbenzene concentrations. Reactor SOA formation was inversely correlated with ambient SOA and Ox , which along with the short-lived volatile organic compound correlation, indicates the importance of very reactive (τOH 0.3 day) SOA precursors (most likely semivolatile and intermediate volatility species, S/IVOCs) in the Greater Los Angeles Area. Evolution of the elemental composition in the reactor was similar to trends observed in the atmosphere (O : C vs. H:C slope -0.65). Oxidation state of carbon (OSc) in reactor SOA increased steeply with age and remained elevated (OSC 2) at the highest photochemical ages probed. The ratio of OA in the reactor output to excess CO (ΔCO, ambient CO above regional background) vs. photochemical age is similar to previous studies at low to moderate ages and also extends to higher ages where OA loss dominates. The mass added at low-to-intermediate ages is due primarily to condensation of oxidized species, not heterogeneous oxidation. The OA decrease at high photochem- ical ages is dominated by heterogeneous oxidation followed by fragmentation/evaporation. A comparison of urban SOA formation in this study with a similar study of vehicle SOA in a tunnel suggests the importance of vehicle emissions for urban SOA. Pre-2007 SOA models underpredict SOA formation by an order of magnitude, while a more recent model performs better but overpredicts at higher ages. These results demonstrate the value of the reactor as a tool for in situ evaluation of the SOA formation potential and OA evolution from ambient air.
AB - Field studies in polluted areas over the last decade have observed large formation of secondary organic aerosol (SOA) that is often poorly captured by models. The study of SOA formation using ambient data is often confounded by the effects of advection, vertical mixing, emissions, and variable degrees of photochemical aging. An oxidation flow reactor (OFR) was deployed to study SOA formation in real-time during the California Research at the Nexus of Air Quality and Climate Change (CalNex) campaign in Pasadena, CA, in 2010. A high-resolution aerosol mass spectrometer (AMS) and a scanning mobility particle sizer (SMPS) alternated sampling ambient and reactor-aged air. The reactor produced OH concentrations up to 4 orders of magnitude higher than in ambient air. OH radical concentration was continuously stepped, achieving equivalent atmospheric aging of 0.8 days- 6.4 weeks in 3 min of processing every 2 h. Enhancement of organic aerosol (OA) from aging showed a maximum net SOA production between 0.8-6 days of aging with net OA mass loss beyond 2 weeks. Reactor SOA mass peaked at night, in the absence of ambient photochemistry and correlated with trimethylbenzene concentrations. Reactor SOA formation was inversely correlated with ambient SOA and Ox , which along with the short-lived volatile organic compound correlation, indicates the importance of very reactive (τOH 0.3 day) SOA precursors (most likely semivolatile and intermediate volatility species, S/IVOCs) in the Greater Los Angeles Area. Evolution of the elemental composition in the reactor was similar to trends observed in the atmosphere (O : C vs. H:C slope -0.65). Oxidation state of carbon (OSc) in reactor SOA increased steeply with age and remained elevated (OSC 2) at the highest photochemical ages probed. The ratio of OA in the reactor output to excess CO (ΔCO, ambient CO above regional background) vs. photochemical age is similar to previous studies at low to moderate ages and also extends to higher ages where OA loss dominates. The mass added at low-to-intermediate ages is due primarily to condensation of oxidized species, not heterogeneous oxidation. The OA decrease at high photochem- ical ages is dominated by heterogeneous oxidation followed by fragmentation/evaporation. A comparison of urban SOA formation in this study with a similar study of vehicle SOA in a tunnel suggests the importance of vehicle emissions for urban SOA. Pre-2007 SOA models underpredict SOA formation by an order of magnitude, while a more recent model performs better but overpredicts at higher ages. These results demonstrate the value of the reactor as a tool for in situ evaluation of the SOA formation potential and OA evolution from ambient air.
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U2 - 10.5194/acp-16-7411-2016
DO - 10.5194/acp-16-7411-2016
M3 - Article
AN - SCOPUS:84974816129
SN - 1680-7316
VL - 16
SP - 7411
EP - 7433
JO - Atmospheric Chemistry and Physics
JF - Atmospheric Chemistry and Physics
IS - 11
ER -