Abstract. Organic nitrates are secondary species in the atmosphere.
Their fate is related to the chemical transport of pollutants from polluted
areas to more distant zones. While their gas-phase chemistry has been
studied, their reactivity in condensed phases is far from being understood.
However, these compounds represent an important fraction of organic matter
in condensed phases. In particular, their partition to the aqueous phase may
be especially important for oxidized organic nitrates for which water
solubility increases with functionalization. This work has studied for the
first time the aqueous-phase ⚫OH-oxidation kinetics of four alkyl
nitrates (isopropyl nitrate, isobutyl nitrate, 1-pentyl nitrate, and
isopentyl nitrate) and three functionalized organic nitrates (α-nitrooxyacetone, 1-nitrooxy-2-propanol, and isosorbide 5-mononitrate) by
developing a novel and accurate competition kinetic method. Low reactivity
was observed, with kOH ranging from 8×107 to 3.1×109 L mol−1 s−1 at 296±2 K. Using these
results, a previously developed aqueous-phase structure–activity
relationship (SAR) was extended, and the resulting parameters confirmed the
extreme deactivating effect of the nitrate group, up to two adjacent carbon
atoms. The achieved extended SAR was then used to determine the ⚫OH-oxidation rate constants of 49 organic nitrates, including hydroxy
nitrates, ketonitrates, aldehyde nitrates, nitrooxy carboxylic acids, and
more functionalized organic nitrates such as isoprene and terpene nitrates.
Their multiphase atmospheric lifetimes towards ⚫OH oxidation were
calculated using these rate constants, and they were compared to their
gas-phase lifetimes. Large differences were observed, especially for
polyfunctional organic nitrates: for 50 % of the proposed organic nitrates
for which the ⚫OH reaction occurs mainly in the aqueous phase (more
than 50 % of the overall removal), their ⚫OH-oxidation lifetimes
increased by 20 % to 155 % under cloud/fog conditions (liquid water content LWC = 0.35 g m−3). In particular, for 83 % of the proposed terpene nitrates, the
reactivity towards ⚫OH occurred mostly (>98 %) in
the aqueous phase, while for 60 % of these terpene nitrates, their
lifetimes increased by 25 % to 140 % compared to their gas-phase
reactivity. We demonstrate that these effects are of importance under
cloud/fog conditions but also under wet aerosol conditions, especially for
the terpene nitrates. These results suggest that considering aqueous-phase
⚫OH-oxidation reactivity of biogenic nitrates is necessary to
improve the predictions of their atmospheric fate.
