posted on 2015-12-16, 21:48authored byCarey L. Friedman, Noelle E. Selin
We use the global 3-D chemical transport model GEOS-Chem
to simulate
long-range atmospheric transport of polycyclic aromatic hydrocarbons
(PAHs). To evaluate the model’s ability to simulate PAHs with
different volatilities, we conduct analyses for phenanthrene (PHE),
pyrene (PYR), and benzo[a]pyrene (BaP). GEOS-Chem captures observed
seasonal trends with no statistically significant difference between
simulated and measured mean annual concentrations. GEOS-Chem also
captures variability in observed concentrations at nonurban sites
(r = 0.64, 0.72, and 0.74, for PHE, PYR, and BaP).
Sensitivity simulations suggest snow/ice scavenging is important for
gas-phase PAHs, and on-particle oxidation and temperature-dependency
of gas-particle partitioning have greater effects on transport than
irreversible partitioning or increased particle concentrations. GEOS-Chem
estimates mean atmospheric lifetimes of <1 day for all three PAHs.
Though corresponding half-lives are lower than the 2-day screening
criterion for international policy action, we simulate concentrations
at the high-Arctic station of Spitsbergen within four times observed
concentrations with strong correlation (r = 0.70,
0.68, and 0.70 for PHE, PYR, and BaP). European and Russian emissions
combined account for ∼80% of episodic high-concentration events
at Spitsbergen.