Abstract
Abstract. Environmental chamber ("smog chamber") experiments were conducted to investigate secondary organic aerosol (SOA) production from dilute emissions from two medium-duty diesel vehicles (MDDVs) and three heavy-duty diesel vehicles (HDDVs) under urban-like conditions. Some of the vehicles were equipped with emission control aftertreatment devices, including diesel particulate filters (DPFs), selective catalytic reduction (SCR) and diesel oxidation catalysts (DOCs). Experiments were also performed with different fuels (100% biodiesel and low-, medium- or high-aromatic ultralow sulfur diesel) and driving cycles (Unified Cycle,~Urban Dynamometer Driving Schedule, and creep + idle). During normal operation, vehicles with a catalyzed DPF emitted very little primary particulate matter (PM). Furthermore, photooxidation of dilute emissions from these vehicles produced essentially no SOA (below detection limit). However, significant primary PM emissions and SOA production were measured during active DPF regeneration experiments. Nevertheless, under reasonable assumptions about DPF regeneration frequency, the contribution of regeneration emissions to the total vehicle emissions is negligible, reducing PM trapping efficiency by less than 2%. Therefore, catalyzed DPFs appear to be very effective in reducing both primary PM emissions and SOA production from diesel vehicles. For both MDDVs and HDDVs without aftertreatment substantial SOA formed in the smog chamber – with the emissions from some vehicles generating twice as much SOA as primary organic aerosol after 3 h of oxidation at typical urban VOC / NOx ratios (3 : 1). Comprehensive organic gas speciation was performed on these emissions, but less than half of the measured SOA could be explained by traditional (speciated) SOA precursors. The remainder presumably originates from the large fraction (~30%) of the nonmethane organic gas emissions that could not be speciated using traditional one-dimensional gas chromatography. The unspeciated organics – likely comprising less volatile species such as intermediate volatility organic compounds – appear to be important SOA precursors; we estimate that the effective SOA yield (defined as the ratio of SOA mass to reacted precursor mass) was 9 ± 6% if both speciated SOA precursors and unspeciated organics are included in the analysis. SOA production from creep + idle operation was 3–4 times larger than SOA production from the same vehicle operated over the Urban Dynamometer Driving Schedule (UDDS). Fuel properties had little or no effect on primary PM emissions or SOA formation.
Highlights
Numerous studies have shown that organic aerosol is a major component of atmospheric fine particulate matter (PM2.5) (Kanakidou et al, 2005) and that secondary organic aerosol (SOA) – formed in the atmosphere from the oxidation of organic vapors – often exceeds the organic aerosol directly emitted from sources, even in urban areas (Jimenez et al, 2009; Subramanian et al, 2007; Stone et al, 2009)
We present data from smog chamber experiments investigating the SOA formation from dilute emissions from two medium-duty and three heavy-duty diesel vehicles that were equipped with different aftertreatment technologies, including diesel particulate filters (DPFs) and selective catalytic reduction (SCR)
The third period begins when the UV lights were turned on (MDDV) or the chamber was exposed to sunlight (HDDV)
Summary
Numerous studies have shown that organic aerosol is a major component of atmospheric fine particulate matter (PM2.5) (Kanakidou et al, 2005) and that secondary organic aerosol (SOA) – formed in the atmosphere from the oxidation of organic vapors – often exceeds the organic aerosol directly emitted from sources (primary organic aerosol, or POA), even in urban areas (Jimenez et al, 2009; Subramanian et al, 2007; Stone et al, 2009). Chirico et al (2010) report that, primary PM emissions remained unaffected, SOA production was reduced by more than a factor of 20 for light-duty diesel vehicles equipped with a diesel oxidation catalyst (DOC) This result is consistent with the welldocumented reduction in SOA precursors caused by DOCs (Liu et al, 2008, 2010; Samy and Zielinska, 2010). We present data from smog chamber experiments investigating the SOA formation from dilute emissions from two medium-duty and three heavy-duty diesel vehicles that were equipped with different aftertreatment technologies, including DPFs and SCRs. The vehicles were operated on a chassis dynamometer over standard driving cycles using different fuels (including diesels with a range of aromatic content and 100 % biodiesel). Companion papers summarize (1) the primary emissions data (May et al, 2014), (2) the gas-particle partitioning of POA emissions (May et al, 2013a, b), (3) the SOA formation from on-road gasoline vehicles (Gordon et al, 2013a), and (4) the SOA formation from small off-road engines (Gordon et al, 2013b)
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