Atmospheric Chemistry and Physics Discussions
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2008
10.5194/acpd-8-2715-2008
http://www.atmos-chem-phys-discuss.net/8/2715/2008/
http://www.atmos-chem-phys-discuss.net/8/2715/2008/acpd-8-2715-2008.html
http://www.atmos-chem-phys-discuss.net/8/2715/2008/acpd-8-2715-2008.pdf
2715
2744
2008-02-12
Nanoparticle formation in the exhaust of vehicles running on ultra-low sulfur fuel
Hua Du
huadu@asrc.cestm.albany.edu
Fangqun Yu
Atmospheric Sciences Research Center, State University of New York at Albany, New York 12203, USA
The concern of adverse health impacts from exposure to
vehicle-emitted nanoparticles has been escalating over the past few years.
In order to meet more stringent EPA emission standards for particle mass
emissions, advanced exhaust after-treatment systems such as continuously
regenerating diesel particle filters (CRDPFs) have to be employed on
vehicles and fuel with ultra-low sulfur is to be used. Although CRDPFs were
found to be effective in reducing particle mass emissions, they were
revealed to increase the potential of volatile nanoparticle formation.
Significant nanoparticle concentrations have also been detected for vehicles
running on ultra-low sulfur fuel but without CRDPFs. The main focus of this
paper is the formation and evolution of nanoparticles in exhaust plume under
ultra-low sulfur condition. Such study is necessary to project future
nanoparticle emissions as fuel compositions and after-treatment systems
change. We have carried out a comprehensive quantitative assessment of the
effects of enhanced sulfur conversion efficiency, sulfur storage/release,
and presence of non-volatile cores on nanoparticle formation using a
detailed composition resolved aerosol microphysical model with a recently
improved H<sub>2</sub>SO<sub>4</sub>-H<sub>2</sub>O homogeneous nucleation (BHN) module. Two
well-controlled case studies show good agreement between model predictions
and measurements in terms of particle size distribution and temperature
dependence of particle formation rate, which leads us to conclude that BHN
is the main source of nanoparticles for vehicles equipped with CRDPFs. We
found that the employment of CRDPFs may lead to the higher number
concentration of nanoparticles (but smaller size) in the exhaust of vehicles
running on ultra-low sulfur fuel compared to those emitted from vehicles
running on high sulfur fuel. We have also shown that the sulfate storage and
release effect can lead to significant enhancement in nanoparticle
production under favorable conditions. For vehicles running on ultra-low
sulfur fuel but without CRDPFs, the BHN is negligible; however, the
condensation of low volatile organic compounds on nanometer-sized
non-volatile cores may explain the observed nucleation mode particles.
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