posted on 2019-09-25, 14:44authored byStephanie
M. Berg, Quinn T. Whiting, Joseph A. Herrli, Ronan Winkels, Kristine H. Wammer, Christina K. Remucal
Dissolved
organic matter (DOM) composition influences its ability
to form photochemically produced reactive intermediates (PPRI). While
relationships have been established between bulk DOM properties and
triplet DOM (3DOM) and singlet oxygen (1O2) quantum yields, contradictory evidence exists for hydroxyl
radical (•OH) and hydroxylating species. Furthermore,
little is known about these relationships at the molecular level.
We evaluated DOM composition and photochemical reactivity of water
samples from a wastewater treatment plant and the St. Louis River
in Minnesota and Wisconsin, U.S.A. Bulk characterization using ultraviolet–visible
spectroscopy demonstrates that color and apparent size of DOM decrease
downstream, while molecular composition analysis using Fourier-transform
ion cyclotron resonance mass spectrometry reveals that saturation
and chemodiversity is highest near Lake Superior. 3DOM
quantum yield coefficients and 1O2 quantum yields
increase downstream and correlate strongly with saturated formulas.
Similar results are observed for carbon-normalized photodegradation
rate constants of atorvastatin, carbamazepine, and venlafaxine, which
react primarily with 3DOM and 1O2. In contrast, •OH quantum yields are lowest downstream
and correlate with less saturated, more oxygenated DOM, suggesting
that 3DOM is not its major precursor. Mixed relationships
are observed for DEET, which reacts with multiple PPRI. Molecular-level
compositional data reveal insights into the differing formation pathways
of individual PPRI, but information about specific contaminants is
needed to predict their photochemical fate.