Composition of Light-Duty Motor Vehicle Exhaust Particulate Matter in the Denver, Colorado Area

Cadle, Steven H.; Mulawa, Patricia A.; Hunsanger, Eric C.; Nelson, Ken; Ragazzi, Ronald A.; Barrett, Richard; Gallagher, Gerald L.; Lawson, Douglas R.; Knapp, Kenneth T.; Snow, Richard

doi:10.1021/es9810843

Cited by 192 publications

(137 citation statements)

References 15 publications

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“…Due to the close proximity of the site to the highway and the high volumes of diesel engine traffic (>20,000 per day), this factor is the highest contributor to EC levels (48%), and is likely strongly influenced (indeed, possibly dominated) by diesel engine emissions. The abundant species in this factor are EC, OC, S, Ca, Fe, Si, Al, Ti, Mn, and these are among the typically measured species in vehicular emissions such as Mg, Al, Si, P, S, Cl, Ca, Fe, Cu, Zn, Br, and Pb as reported by Gillies and Gertler (2000) and Cadle et al (1999). The ratio of EC to OC for this factor was 0.43 which is much higher than typically reported for gasoline engine emissions.…”

Section: Unmix Resultsmentioning

confidence: 83%

“…There are several studies that have also indicated the cofounding effects of anthropogenic aerosols (such as industrial emissions, traffic exhausts) and naturally occurring bioaerosols in respiratory disorders (Nel et al, 1998;Takenaka et al, 1995). Emissions from traffic-related sources in urban areas have been examined by several researchers (Cadle et al, 1999;Gillies and Gertler, 2000;HEI, 2002;Schauer et al,1996;Shi et al, 1999). A large cohort epidemiological study is underway in the Greater Cincinnati area to examine the adjuvant role of traffic related and naturally occurring aerosols on enhancing the onset of allergic sensitization in children (LeMasters et al, 2003;Ryan et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

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UNMIX modeling of ambient PM2.5 near an interstate highway in Cincinnati, OH, USA

McDonald

Martuzevičius

et al. 2006

Atmospheric Environment

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The "Cincinnati Childhood Allergy and Air Pollution Study (CCAAPS)" is underway to determine if infants who are exposed to diesel engine exhaust particles are at an increased risk for atopy and atopic respiratory disorders, and to determine if this effect is magnified in a genetically at risk population. In support of this study, a methodology has been developed to allocate local traffic source contributions to ambient PM 2.5 in the Cincinnati airshed. As a first step towards this allocation, UNMIX was used to generate factors for ambient PM 2.5 at two sites near at interstate highway. Procedures adopted to collect, analyze and prepare the data sets to run UNMIX are described. The factors attributed to traffic sources were similar for the two sites. These factors were also similar to locally measured truck engine-exhaust enriched ambient profiles. The temporal variation of the factors was analyzed with clear differences observed between factors attributed to traffic sources and combustion-related regional secondary sources.

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Section: Unmix Resultsmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 99%

UNMIX modeling of ambient PM2.5 near an interstate highway in Cincinnati, OH, USA

McDonald

Martuzevičius

et al. 2006

Atmospheric Environment

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“…A series dynamometer tests had proved that the OC/EC ratio was a good indicator to separate diesel vehicle emission from gasoline vehicle emission. When OC/EC was in the range of 0.3-0.9, PM 2.5 was mainly derived from the diesel vehicle, and when OC/EC is larger than 2.0, PM 2.5 was primarily from gasoline car (Cadle et al, 1999;Liu et al, 2012). OC/EC in WZS tunnel ranged from 0.48 to 1.45 with an average value of 0.86.…”

Section: Oc and Ecmentioning

confidence: 99%

Chemical composition of PM 2.5 from two tunnels with different vehicular fleet characteristics

Cui

Chen

Tian

et al. 2016

Science of The Total Environment

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• Composition profiles of PM 2.5 were obtained in smaller city, Yantai.• Characteristics of PM 2.5 were changed by emission standards and fuel policy.• Source profiles of PM 2.5 for gasoline vehicles and diesel vehicles were given.• The diesel vehicles play a major role in PM 2.5 emissions in Yantai. The chemical compositions of PM 2.5 including OC, EC, water soluble ions, elements, and organic components such as polycyclic aromatic hydrocarbons (PAHs), hopanes, and steranes, emitted in Wuzushan (WZS) and Kuixinglou (KXL) tunnels were determined. WZS tunnel is a major route for diesel vehicles traveling, while KXL tunnel has limited to diesel vehicles. The results showed that the proportions of the different constituents of PM 2.5 in the Wuzushan (WZS) tunnel were OC (27.7%), EC (32.1%), elements (13.9%), and water soluble ions (9.2%). Whereas the chemical profile of PM 2.5 in the Kuixinglou (KXL) tunnel was OC (17.7%), EC (10.4%), elements (8.90%), and water soluble ions (8.87%). The emission factors (EFs) of PM 2.5 and proportions of SO 4 2− and Pb were decreased by vehicle emission standards and fuel quality policy in China, and the higher molecular weight PAHs (4 + 5 + 6 rings) were more abundant than the lower molecular weight PAHs (2 + 3 rings) in the two tunnels. The proportions of 17A(H)-21B(H)-30-Norhopane and 17A(H)-21B(H)-Hopane in the hopane and sterane were not dependent on the vehicles types. In addition, specific composition profiles for PM 2.5 from gasoline-fueled vehicles (GV) G R A P H I C A L A B S T R A C T a b s t r a c t a r t i c l e i n f o Contents lists available at ScienceDirectScience of the Total Environment j o u r n a l h o m e p a g e : w w w . e l s e v i e r . c o m / l o c a t e / s c i t o t e n v and diesel-fueled vehicles (DV) emissions were drafted, which indicated that OC (0.974 mg·veh −1 ·km −1 ) was the most abundant component in PM 2.5 , followed by Fe, Cl − , and Mg for GV. The relative proportions of the different constituents in the PM 2.5 for DV were EC (35.9%), OC (27.2%), elements (12.8%), and water soluble ions (11.7%). Both the PM 2.5 EFs and EC proportions in DV were higher than those in GV, and the HMW PAHs were the dominant PAHs for both GV and DV. The PM 2.5 emissions from the vehicles in Yantai were 581 ± 513 tons to 1353 ± 1197 tons for GV, and 19,627 ± 2477 tons to 23,042 ± 2887 tons for DV, respectively.

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“…Currently, only limited measurements of ECOC for diesel engine emissions exist that utilize the NIOSH and IM-PROVE ECOC measurement techniques. A sample of these measurements, which are shown in Table 3, shows that under standardized driving cycle conditions; the EC to TC ratio of diesel particulate matter is in the range of 0.50-0.80 (Hildemann et al, 1991;Lowenthal et al, 1994;Watson et al, 1998;Cadle et al, 1999;Schauer et al, 1999b). Reported measurements of this nature are not sufficient to elucidate the effect of driving cycle, engine type, engine age, and engine fuel on this ratio but they can be expected to be important factors.…”

Section: Atmospheric Sources Of Elemental Carbonmentioning

confidence: 99%

“…e Profile 2, which includes only buses and trucks without particle traps and operated on diesel fuel. powered motor vehicles that have a visible smoke plume, often called smokers, has been measured to be in the range of 0.14 in Denver, Colorado using the IMPROVE ECOC method (Cadle et al, 1999). During the same study, nonsmoking vehicles were measured to have elemental contributions to total particulate carbon of 0.27 and 0.38 for summer and winter tests, respectively.…”

Section: Atmospheric Sources Of Elemental Carbonmentioning

confidence: 99%

Evaluation of elemental carbon as a marker for diesel particulate matter

Schauer

2003

J Expo Sci Environ Epidemiol

219

123

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Elemental carbon (EC) in atmospheric particulate matter originates from a broad range of sources in many urban locations. As health and air quality studies are using elemental carbon measurements to better understand the impact of diesel engines and other combustion sources, there is a great need to clearly understand the relative source contributions to EC concentrations in the atmosphere. However, the different analytical techniques currently used to measure EC do not show good agreement for many particulate matter samples. To this end, studies that use EC as a tracer and integrate different analytical techniques for EC can significantly bias estimates of source contributions to atmospheric particulate matter. In addition, source attribution studies that do not properly address all sources of EC in the atmosphere can also lead to inaccuracies and biases. To better understand the use of EC as a tracer, a review of the distribution of EC in the primary particulate matter emissions from air pollution sources using different analytical methods is discussed. A review of previous apportionment studies of particulate matter is presented to elucidate the fraction of EC that results from emissions from diesel engines in urban locations. These results demonstrate that EC is not a unique tracer for diesel exhaust and efforts to utilize EC as an indicator of diesel exhaust must properly address other sources of EC as well as utilize a consistent measurement technique for EC when comparing source and ambient EC measurements to avoid significant biases.

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Composition of Light-Duty Motor Vehicle Exhaust Particulate Matter in the Denver, Colorado Area

Cited by 192 publications

References 15 publications

UNMIX modeling of ambient PM2.5 near an interstate highway in Cincinnati, OH, USA

UNMIX modeling of ambient PM2.5 near an interstate highway in Cincinnati, OH, USA

Chemical composition of PM 2.5 from two tunnels with different vehicular fleet characteristics

Evaluation of elemental carbon as a marker for diesel particulate matter

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