Polycyclic aromatic hydrocarbons (PAHs) undergo transformation reactions with atmospheric photochemical oxidants, such as hydroxyl radicals (OH•), nitrogen oxides (NOx), and ozone (O 3 ). The most common PAH-transformation products (PAH-TPs) are nitrated-, oxygenated-, and hydroxylated-PAHs (NPAHs, OPAHs, and OHPAHs, respectively), some of which are known to pose potential human health concerns. We sampled four theoretical approaches for predicting the location of reactive sites on PAHs (i.e., the carbon where atmospheric oxidants attack), and hence the chemoselectivity of the PAHs. All computed results are based on Density Functional Theory (B3LYP/6-31G(d) optimized structures and energies). The four approaches are: 1) Clar's prediction of aromatic resonance structures, 2) thermodynamic stability of all OHPAH adduct intermediates, 3) computed atomic charges (Natural Bond order, ChelpG, and Mulliken) at each carbon on the PAH, and 4) average local ionization energy (ALIE) at atom or bond sites. To evaluate the accuracy of these approaches, the predicted PAH-TPs were compared to published laboratory observations of major NPAH, OPAH, and OHPAH products in both gas-and particlephases. We found that the Clar's resonance structures were able to predict the least stable rings on the PAHs but did not offer insights in terms of which individual carbon is most reactive. The OHPAH adduct thermodynamics and the ALIE approaches were the most accurate when *
Characterizing
the chemical composition of organic aerosols can
elucidate aging mechanisms as well as the chemical and physical properties
of the aerosol. However, the high chemical complexity and often low
atmospheric abundance present a difficult analytical challenge. Milligrams
or more of material may be needed for speciated spectroscopic analysis.
In contrast, mass spectrometry provides a very sensitive platform
but limited structural information. Here, we combine the strengths
of mass spectrometry and infrared (IR) action spectroscopy to generate
characteristic IR spectra of individual, mass-isolated ion populations.
Soft ionization combined with in situ infrared ion spectroscopy, using
the tunable free-electron laser FELIX, provides detailed information
on molecular structures and functional groups. We apply this technique,
along with quantum mechanical modeling, to characterize organic molecules
in secondary organic aerosol (SOA) formed from the ozonolysis of α-pinene.
Spectral overlap with a standard is used to identify cis-pinonic acid. We also demonstrate the characterization of isomers
for multiple SOA products using both quantum mechanical computations
and analyses of fragment ion spectra. These results demonstrate the
detailed structural information on isolated ions obtained by combining
mass spectrometry with fingerprint IR spectroscopy.
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