posted on 2017-08-21, 00:00authored byBeth Friedman, Michael F. Link, S. Ryan Fulgham, Patrick Brophy, Abril Galang, William H. Brune, Shantanu H. Jathar, Delphine K. Farmer
Organic
acids have primary and secondary sources in the atmosphere,
impact ecosystem health, and are useful metrics for identifying gaps
in organic oxidation chemistry through model-measurement comparisons.
We photooxidized (OH oxidation) primary emissions from diesel and
biodiesel fuel types under two engine loads in an oxidative flow reactor.
formic, butyric, and propanoic acids, but not methacrylic acid, have
primary and secondary sources. Emission factors for these gas-phase
acids varied from 0.3–8.4 mg kg–1 fuel. Secondary
chemistry enhanced these emissions by 1.1 (load) to 4.4 (idle) ×
after two OH-equivalent days. The relative enhancement in secondary
organic acids in idle versus loaded conditions was due to increased
precursor emissions, not faster reaction rates. Increased hydrocarbon
emissions in idle conditions due to less complete combustion (associated
with less oxidized gas-phase molecules) correlated to higher primary
organic acid emissions. The lack of correlation between organic aerosol
and organic acid concentrations downstream of the flow reactor indicates
that the secondary products formed on different oxidation time scales
and that despite being photochemical products, organic acids are poor
tracers for secondary organic aerosol formation from diesel exhaust.
Ignoring secondary chemistry from diesel exhaust would lead to underestimates
of both organic aerosol and gas-phase organic acids.