Abstract. Gasoline vehicles significantly contribute to urban particulate
matter (PM) pollution. Gasoline direct injection (GDI) engines, known for
their higher fuel efficiency than that of port fuel injection (PFI) engines,
have been increasingly employed in new gasoline vehicles. However, the impact
of this trend on air quality is still poorly understood. Here, we
investigated both primary emissions and secondary organic aerosol (SOA)
formation from a GDI and a PFI vehicle under an urban-like driving condition,
using combined approaches involving chassis dynamometer measurements and
an environmental chamber simulation. The PFI vehicle emits slightly more
volatile organic compounds, e.g., benzene and toluene, whereas the GDI
vehicle emits more particulate components, e.g., total PM, elemental
carbon, primary organic aerosols and polycyclic aromatic hydrocarbons.
Strikingly, we found a much higher SOA production (by a factor of
approximately 2.7) from the exhaust of the GDI vehicle than that of the PFI
vehicle under the same conditions. More importantly, the higher SOA
production found in the GDI vehicle exhaust occurs concurrently with lower
concentrations of traditional SOA precursors, e.g., benzene and toluene,
indicating a greater contribution of intermediate volatility organic
compounds and semi-volatile organic compounds in the GDI vehicle exhaust to
the SOA formation. Our results highlight the considerable potential
contribution of GDI vehicles to urban air pollution in the future.
Comparison of primary aerosol emission and secondary aerosol formation from gasoline direct injection and port fuel injection vehicles
