SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4247866709> ?p ?o ?g. }

Showing items 1 to 100 of ±161 with 100 items per page.

W4247866709 abstract "Abstract. We report the first hourly in-situ measurements of speciated organic aerosol (OA) composition in an urban environment. Field measurements were made in southern California at the University of California–Riverside during the 2005 Study of Organic Aerosol at Riverside (SOAR), which included two separate measurement periods: a summer study (15 July–15 August) and a fall study (31 October–28 November). Hourly measurements of over 300 semivolatile and nonvolatile organic compounds were made using the thermal desorption aerosol gas chromatograph (TAG). Positive matrix factorization (PMF) was performed on a subset of these compounds to identify major components contributing to submicron (i.e., PM1) OA at the site, as measured by an aerosol mass spectrometer (AMS). PMF analysis was performed on an 11-day focus period in each season, representing average seasonal conditions during the summer and a period of urban influence during the fall. As a result of this analysis, we identify multiple types of primary and secondary OA (POA and SOA). Secondary sources contribute substantially to fine OA mass at Riverside, which commonly receives regional air masses that pass through metropolitan Los Angeles during the summer. Four individual summertime SOA components are defined, and when combined, they contribute an average 88% of the total fine OA mass during summer afternoons. These sources appear to be mostly from the oxidation of anthropogenic precursor gases, with one SOA component having contributions from oxygenated biogenics. During the fall, three out of four aerosol components which contain SOA are inseparable from covarying primary emissions, and therefore we can not estimate the fraction of total OA that is secondary in nature during the fall study. Identified primary OA components are attributed to vehicle emissions, food cooking, primary biogenics, and biomass burning aerosol. While a distinction between local and regional vehicle emissions is made, a combination of these two factors accounted for approximately 11% of observed submicron OA during both sampling periods. Food cooking operations contributed ~10% of submicron OA mass during the summer, but was not separable from SOA during the fall due to high covariance of sources. Biomass burning aerosol contributed a larger fraction of fine OA mass during the fall (~11%) than compared to summer (~7%). Primary biogenic aerosol was also identified during the summer, contributing ~1% of the OA, but not during the fall. While the contribution of both local and regional primary vehicle OA accounts for only ~11% of total OA during both seasons, gas-phase vehicle emissions likely create a substantial fraction of the observed SOA as a result of atmospheric processing." @default.
W4247866709 created "2022-05-12" @default.
W4247866709 creator A5026978286 @default.
W4247866709 creator A5029810906 @default.
W4247866709 creator A5032035737 @default.
W4247866709 creator A5041007958 @default.
W4247866709 creator A5059868424 @default.
W4247866709 creator A5063007042 @default.
W4247866709 creator A5070739659 @default.
W4247866709 creator A5080732025 @default.
W4247866709 date "2010-03-09" @default.
W4247866709 modified "2023-09-22" @default.
W4247866709 title "Major components of atmospheric organic aerosol in southern California as determined by hourly measurements of source marker compounds" @default.
W4247866709 cites W1561878391 @default.
W4247866709 cites W1964400493 @default.
W4247866709 cites W1966626986 @default.
W4247866709 cites W1968862760 @default.
W4247866709 cites W1969061516 @default.
W4247866709 cites W1971194805 @default.
W4247866709 cites W1971502226 @default.
W4247866709 cites W1975266316 @default.
W4247866709 cites W1984993155 @default.
W4247866709 cites W1985285298 @default.
W4247866709 cites W1986615978 @default.
W4247866709 cites W1988591536 @default.
W4247866709 cites W1988963778 @default.
W4247866709 cites W1990667021 @default.
W4247866709 cites W1998111035 @default.
W4247866709 cites W2003514756 @default.
W4247866709 cites W2007777005 @default.
W4247866709 cites W2009216468 @default.
W4247866709 cites W2009761601 @default.
W4247866709 cites W2009804295 @default.
W4247866709 cites W2009837182 @default.
W4247866709 cites W2016935109 @default.
W4247866709 cites W2017530241 @default.
W4247866709 cites W2018331359 @default.
W4247866709 cites W2019566939 @default.
W4247866709 cites W2021198116 @default.
W4247866709 cites W2022130129 @default.
W4247866709 cites W2025100133 @default.
W4247866709 cites W2025772648 @default.
W4247866709 cites W2026275622 @default.
W4247866709 cites W2028021822 @default.
W4247866709 cites W2029604856 @default.
W4247866709 cites W2030601441 @default.
W4247866709 cites W2031691972 @default.
W4247866709 cites W2035527406 @default.
W4247866709 cites W2036676959 @default.
W4247866709 cites W2039476700 @default.
W4247866709 cites W2040411940 @default.
W4247866709 cites W2044295262 @default.
W4247866709 cites W2045504515 @default.
W4247866709 cites W2045931830 @default.
W4247866709 cites W2051545938 @default.
W4247866709 cites W2054552851 @default.
W4247866709 cites W2056857971 @default.
W4247866709 cites W2060923657 @default.
W4247866709 cites W2062609292 @default.
W4247866709 cites W2063165760 @default.
W4247866709 cites W2063395107 @default.
W4247866709 cites W2068890460 @default.
W4247866709 cites W2072883046 @default.
W4247866709 cites W2073376626 @default.
W4247866709 cites W2075424611 @default.
W4247866709 cites W2075446874 @default.
W4247866709 cites W2078057183 @default.
W4247866709 cites W2078321221 @default.
W4247866709 cites W2079355115 @default.
W4247866709 cites W2080955504 @default.
W4247866709 cites W2081118881 @default.
W4247866709 cites W2089287817 @default.
W4247866709 cites W2090210927 @default.
W4247866709 cites W2094642873 @default.
W4247866709 cites W2095337637 @default.
W4247866709 cites W2102028191 @default.
W4247866709 cites W2103424506 @default.
W4247866709 cites W2110547016 @default.
W4247866709 cites W2113673259 @default.
W4247866709 cites W2116015342 @default.
W4247866709 cites W2116968886 @default.
W4247866709 cites W2119744638 @default.
W4247866709 cites W2127510753 @default.
W4247866709 cites W2135261835 @default.
W4247866709 cites W2135400312 @default.
W4247866709 cites W2139686657 @default.
W4247866709 cites W2144075611 @default.
W4247866709 cites W2144923407 @default.
W4247866709 cites W2145123870 @default.
W4247866709 cites W2148099625 @default.
W4247866709 cites W2149095269 @default.
W4247866709 cites W2149153812 @default.
W4247866709 cites W2165729402 @default.
W4247866709 cites W2168143240 @default.
W4247866709 cites W2318698569 @default.
W4247866709 cites W2427702933 @default.
W4247866709 doi "https://doi.org/10.5194/acpd-10-6567-2010" @default.
W4247866709 hasPublicationYear "2010" @default.
W4247866709 type Work @default.
W4247866709 citedByCount "5" @default.