Your search keyword '"Zhang, Xiaolu"' showing total 2 results

1. Organic Aerosol Particle Chemical Properties Associated With Residential Burning and Fog in Wintertime San Joaquin Valley (Fresno) and With Vehicle and Firework Emissions in Summertime South Coast Air Basin (Fontana).

Author

Chen, Chia‐Li, Chen, Sijie, Russell, Lynn M., Liu, Jun, Price, Derek J., Betha, Raghu, Sanchez, Kevin J., Lee, Alex K. Y., Williams, Leah, Collier, Sonya C., Zhang, Qi, Kumar, Anikender, Kleeman, Michael J., Zhang, Xiaolu, and Cappa, Christopher D.

Subjects

AEROSOLS, PARTICLES, CHEMICAL properties, AIR pollution, FOG, WINTER, AUTOMOBILE emissions

Abstract

Organic aerosol mass (OM) components were investigated at Fresno in winter and at Fontana in summer by positive matrix factorization of high‐resolution time‐of‐flight aerosol mass spectra and of Fourier Transform infrared spectra, as well as by k‐means clustering of light‐scattering (LS) aerosol single‐particle spectra. The results were comparable for all three methods at both sites, showing different contributions of primary and secondary organic aerosol sources to PM1. At Fresno biomass burning organic aerosol contributed 27% of OM on low‐fog days, and nitrate‐related oxidized OA (NOOA) accounted for 47% of OM on high‐fog days, whereas at Fontana very oxygenated organic aerosol (VOOA) components contributed 58–69% of OM. Amine and organosulfate fragment concentrations were between 2 and 3 times higher on high‐fog days than on low‐fog days at Fresno, indicating increased formation from fog‐related processes. NOOA and biomass burning organic aerosol components were largely on different particles than the VOOA components in Fresno, but in Fontana both NOOA and VOOA components were distributed on most particle types, consistent with a longer time for and a larger contribution from gas‐phase photochemical secondary organic aerosol formation in summer Fontana than winter Fresno. Uncommon trace organic fragments, elevated inorganic, and alcohol group submicron mass concentrations persisted at Fontana for more than 5 days after 4 July fireworks. These unique aerosol chemical compositions at Fresno and Fontana show substantial and extended air‐quality impacts from residential burning and fireworks. Key Points: Oxidized organic and amine fragment concentrations were higher on high‐fog days than on low‐fog days at FresnoUncommon trace organic fragments (m/z 27 and m/z 63), nitrate, sulfate, and single‐particle types associated with fireworks persisted at high concentrations at Fontana for 5 days after emissionNitrate‐related and other organic aerosol mass factors were largely on different particle types at Fresno but were mixed at Fontana [ABSTRACT FROM AUTHOR]

Published

2018

2. Larger Submicron Particles for Emissions With Residential Burning in Wintertime San Joaquin Valley (Fresno) than for Vehicle Combustion in Summertime South Coast Air Basin (Fontana).

Author

Betha, Raghu, Russell, Lynn M., Chen, Chia‐Li, Liu, Jun, Price, Derek J., Sanchez, Kevin J., Chen, Sijie, Lee, Alex K. Y., Zhang, Qi, Collier, Sonya C., Zhang, Xiaolu, and Cappa, Christopher D.

Subjects

PARTICLES, EMISSIONS (Air pollution), WINTER, AUTOMOBILE engine combustion, SUMMER, SOUTH Coast (Fla.)

Abstract

Size‐resolved composition of atmospheric aerosol particles during winter (19 December 2014 to 13 January 2015) in the San Joaquin Valley at Fresno and during summer (4 to 28 July 2015) in the Southern California Air Basin at Fontana were measured by aerosol mass spectrometer, Fourier transform infrared spectrometer, single particle soot photometer, and scanning electrical mobility sizer. The Fresno study had low‐fog and high‐fog winter conditions, and residential burning was a frequent contributor to evening emissions. Fireworks during Fourth of July celebrations characterized the start of the Fontana study; the remaining days were categorized as nonfirework days and were mostly affected by traffic emissions. Fresno had particle distributions with number mode diameters of 70–150 nm, and Fontana had 30–50‐nm diameters. The nonrefractory organic mass mode diameters were also larger at Fresno (250–380 nm in dry mobility diameter) than at Fontana (130–150 nm, 280 nm in dry mobility diameter) as were refractory black carbon particles (Fresno: 80–180 nm; Fontana: 80–100 nm in dry volume equivalent diameter). The size dependence of organic contributions to particle mass indicated that condensation or other surface‐limited processes contributed oxidized organic fractions to aerosol mass in Fontana but that volume‐limited aqueous reactions produced organic mass on both low‐fog and high‐fog days in Fresno. Linear regression analysis of organic aerosol sources with size‐resolved particle volume at different times of day also showed that residential burning‐related particles increased from 70–160 nm in the evening (18:00 to 23:59) to 150–260 nm at night (00:00 to 05:59) on low‐fog days. Key Points: In Fresno, residential wood burning contributions resulted in larger mass (300‐460 nm) and number (70‐150 nm) mode diametersIn Fontana, vehicle emissions and secondary aerosol components produced smaller mass (120‐310 nm) and number (30‐50 nm) mode diametersSurface‐limited processes in Fontana and volume‐limited aqueous reactions in Fresno contributed to secondary organic mass [ABSTRACT FROM AUTHOR]

Published

2018