Measurements of Nanoparticles of Organic Carbon and Soot in Flames and Vehicle Exhausts

Sgro, Lee Anne; Borghese, A.; Speranza, Luciano; Barone, A.; Minutolo, P.; Bruno, Annalisa; D’Anna, Andrea; D’Alessio, Antonio

doi:10.1021/es070485s

Cited by 51 publications

(59 citation statements)

References 18 publications

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“…It is suggested that they are carbonaceous particles formed during combustion. 20,21 Negative health effects of particle emissions [22][23][24][25] have driven stricter emission standards for diesel particulate emissions. More stringent traffic emission limits drive engine and vehicle manufacturers to utilize new technologies to reduce emissions.…”

Section: Discussionmentioning

confidence: 99%

“…The origin or composition of these nonvolatile particles in unknown, but it has been suggested that they are heavy HCs formed during combustion. 20,21 Effect of DOC ؉ POC on Particles When the engine was equipped with the DOC ϩ POC combination, no nucleation-mode particles were detected at any of the four load points. This is shown in Figure 3, where the size distributions measured with and without the thermodenuder are shown.…”

Section: Particle Size Distributionsmentioning

confidence: 99%

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Effect of Open Channel Filter on Particle Emissions of Modern Diesel Engine

Heikkilä

Rönkkö

Lähde

et al. 2009

Journal of the Air & Waste Management Association

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Particle emissions of modern diesel engines are of a particular interest because of their negative health effects. The special interest is in nanosized solid particles. The effect of an open channel filter on particle emissions of a modern heavy-duty diesel engine (MAN D2066 LF31, model year 2006) was studied. Here, the authors show that the open channel filter made from metal screen efficiently reduced the number of the smallest particles and, notably, the number and mass concentration of soot particles. The filter used in this study reached 78% particle mass reduction over the European Steady Cycle. Considering the size-segregated number concentration reduction, the collection efficiency was over 95% for particles smaller than 10 nm. The diffusion is the dominant collection mechanism in small particle sizes, thus the collection efficiency decreased as particle size increased, attaining 50% at 100 nm. The overall particle number reduction was 66 -99%, and for accumulation-mode particles the number concentration reduction was 62-69%, both depending on the engine load.

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Section: Discussionmentioning

confidence: 99%

Section: Particle Size Distributionsmentioning

confidence: 99%

Effect of Open Channel Filter on Particle Emissions of Modern Diesel Engine

Heikkilä

Rönkkö

Lähde

et al. 2009

Journal of the Air & Waste Management Association

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“…Owing to their small size and complicated chemical and physical characteristics (3)(4)(5)(6), atmospheric particles resulting from traffic emissions pose a significant risk to human health (7)(8)(9)(10)(11)(12), and also contribute to anthropogenic forcing of climate (13,14). Previous research on vehicular emissions has demonstrated the presence of soot and ash (3,15) and solid sub-10-nm core particles (4)(5)(6) in primary emissions from vehicles and engines and their variation, depending on vehicle technologies (4,6), the properties of fuels and lubricant oils (15,16), and driving conditions (15)(16)(17). In addition to particles, exhaust typically contains species that reside in the gaseous phase in the undiluted high-temperature exhaust (5,18,19) but condense or even nucleate to the particle phase immediately after the exhaust is released to the atmosphere.…”

mentioning

confidence: 99%

“…Some studies have also shown that nanosized clusters have a role in engine emission formation (4,25). Research on particle number concentrations near traffic has shown highly elevated concentrations (of the order of 10 5 -10 6 ) of ultrafine particles near roadways (2,26), also indicating the likelihood of high concentrations of nanosized particles and clusters existing in such environments.…”

mentioning

confidence: 99%

Traffic is a major source of atmospheric nanocluster aerosol

Rönkkö

Kuuluvainen

Karjalainen

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

203

132

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In densely populated areas, traffic is a significant source of atmospheric aerosol particles. Owing to their small size and complicated chemical and physical characteristics, atmospheric particles resulting from traffic emissions pose a significant risk to human health and also contribute to anthropogenic forcing of climate. Previous research has established that vehicles directly emit primary aerosol particles and also contribute to secondary aerosol particle formation by emitting aerosol precursors. Here, we extend the urban atmospheric aerosol characterization to cover nanocluster aerosol (NCA) particles and show that a major fraction of particles emitted by road transportation are in a previously unmeasured size range of 1.3-3.0 nm. For instance, in a semiurban roadside environment, the NCA represented 20-54% of the total particle concentration in ambient air. The observed NCA concentrations varied significantly depending on the traffic rate and wind direction. The emission factors of NCA for traffic were 2.4·10 15 (kg fuel ) −1 in a roadside environment, 2.6·10 15 (kg fuel ) −1 in a street canyon, and 2.9·10 15 (kg fuel ) −1 in an on-road study throughout Europe. Interestingly, these emissions were not associated with all vehicles. In engine laboratory experiments, the emission factor of exhaust NCA varied from a relatively low value of 1.6·10 12 (kg fuel ) −1 to a high value of 4.3·10 15 (kg fuel ) −1 . These NCA emissions directly affect particle concentrations and human exposure to nanosized aerosol in urban areas, and potentially may act as nanosized condensation nuclei for the condensation of atmospheric low-volatile organic compounds.nanocluster aerosol | atmospheric aerosol | combustion-derived nanoparticles | air pollution | traffic emission D etailed characterization of aerosol sources is required to understand climate impacts and health effects of atmospheric aerosols, as well as to develop technologies and policies capable of mitigating air pollution in urbanized areas. In densely populated areas, one of the most significant source of particles is traffic (1, 2). Owing to their small size and complicated chemical and physical characteristics (3-6), atmospheric particles resulting from traffic emissions pose a significant risk to human health (7-12), and also contribute to anthropogenic forcing of climate (13,14). Previous research on vehicular emissions has demonstrated the presence of soot and ash (3, 15) and solid sub-10-nm core particles (4-6) in primary emissions from vehicles and engines and their variation, depending on vehicle technologies (4, 6), the properties of fuels and lubricant oils (15, 16), and driving conditions (15-17). In addition to particles, exhaust typically contains species that reside in the gaseous phase in the undiluted high-temperature exhaust (5, 18, 19) but condense or even nucleate to the particle phase immediately after the exhaust is released to the atmosphere. Here, we term such aerosols delayed primary aerosols, because particle precursors exist already in the u...

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“…Thermal and diffusion charging mechanisms are explored to explain the measured charge distributions, and we discuss the implications of the results for particle coagulation at high temperature. The particles are produced in atmospheric pressure premixed flames, which have been previously examined with many complementary particle diagnostics with sensitivity to particles/macromolecules as small as 1 nm, including multiwavelength optical, microscopy and mobility measurements (D'Alessio et al 2005Minutolo et al 1999;Sgro et al 2008). While the various measurement techniques are in excellent agreement in flame conditions that eventually produce particles larger than 3-5 nm, the DMA measurements are significantly lower than in situ optical measurements in flame conditions where the size distribution is unimodal with a modal diameter, d modal ∼ 2 nm ).…”

Section: Introductionmentioning

confidence: 99%

Charge Distribution of Incipient Flame-Generated Particles

Sgro

D’Anna

Minutolo

2010

Aerosol Science and Technology

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We report the size and electrical charge distributions of incipient nanoparticles generated in atmospheric pressure hydrocarbon/air premixed flames in conditions prior to the onset of soot particles. The particle size and charge distributions are measured by Differential Mobility Analysis (DMA) and compared to theoretical charge distributions predicted for flame conditions. The results show that the charge distribution attained in flames is well predicted by Boltzmann theory for all particles, including even the smallest incipient particles with diameters in the 1-3 nm size range. In flame conditions that produce only particles smaller than 3 nm, the charge fraction of particles agrees with that predicted by Boltzmann theory near the flame temperature (1700 K). In flame conditions with 'bimodal' particle size distributions, the charge fraction of the smallest particles agrees with the Boltzmann prediction at maximum flame temperature, while the charge fractions of larger particles agree with Boltzmann theory at temperatures that coincide with the local temperature near the probe surface (1000-1200 K). The results of this paper show that the temperature of the Boltzmann charge fraction that best agrees with the measured charge fraction for each particle size gives the local temperature of their last coagulation event. The smaller particles, which retain their charge fraction predicted by Boltzmann at the maximum flame temperature, do not thermalize by coagulation in the cool region near the probe evidencing low probability for charge transfer as well as for coagulation.

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Measurements of Nanoparticles of Organic Carbon and Soot in Flames and Vehicle Exhausts

Cited by 51 publications

References 18 publications

Effect of Open Channel Filter on Particle Emissions of Modern Diesel Engine

Effect of Open Channel Filter on Particle Emissions of Modern Diesel Engine

Traffic is a major source of atmospheric nanocluster aerosol

Charge Distribution of Incipient Flame-Generated Particles

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