Abstract. We present the first direct measurements of NO3 reactivity (or
inverse lifetime, s−1) in the Finnish boreal forest. The data were
obtained during the IBAIRN campaign (Influence of Biosphere-Atmosphere
Interactions on the Reactive Nitrogen budget) which took place in
Hyytiälä, Finland during the summer/autumn transition in
September 2016. The NO3 reactivity was generally very high with a
maximum value of 0.94 s−1 and displayed a strong diel variation with a
campaign-averaged nighttime mean value of 0.11 s−1 compared to a
daytime value of 0.04 s−1. The highest nighttime NO3 reactivity
was accompanied by major depletion of canopy level ozone and was associated
with strong temperature inversions and high levels of monoterpenes. The
daytime reactivity was sufficiently large that reactions of NO3 with
organic trace gases could compete with photolysis and reaction with NO. There
was no significant reduction in the measured NO3 reactivity between
the beginning and end of the campaign, indicating that any seasonal reduction
in canopy emissions of reactive biogenic trace gases was offset by emissions
from the forest floor. Observations of biogenic hydrocarbons (BVOCs) suggested
a dominant role for monoterpenes in determining the NO3 reactivity.
Reactivity not accounted for by in situ measurement of NO and BVOCs was
variable across the diel cycle with, on average, ≈ 30 %
“missing” during nighttime and ≈ 60 % missing during the day.
Measurement of the NO3 reactivity at various heights (8.5 to 25 m)
both above and below the canopy, revealed a strong nighttime, vertical
gradient with maximum values closest to the ground. The gradient disappeared
during the daytime due to efficient vertical mixing.
Abstract. We present an estimation of the uptake coefficient (γ ) and yield of nitryl chloride (ClNO 2 ) (f ) for the heterogeneous processing of dinitrogen pentoxide (N 2 O 5 ) using simultaneous measurements of particle and trace gas composition at a semi-rural, non-coastal, mountain site in the summer of 2011. The yield of ClNO 2 varied between (0.035 ± 0.027) and (1.38 ± 0.60) with a campaign average of (0.49 ± 0.35). The large variability in f reflects the highly variable chloride content of particles at the site. Uptake coefficients were also highly variable with minimum, maximum and average γ values of 0.004, 0.11 and 0.028 ± 0.029, respectively, with no significant correlation with particle composition, but a weak dependence on relative humidity. The uptake coefficients obtained are compared to existing parameterizations based on laboratory datasets and with other values obtained by analysis of field data.
Abstract. Through measurements of NO2, O3 and NO3 during the PARADE campaign (PArticles and RAdicals, Diel observations of mEchanisms of oxidation) in the German Taunus mountains we derive nighttime steady-state lifetimes (τss) of NO3 and N2O5. During some nights, high NO3 (∼ 200 pptv) and N2O5 (∼ 1 ppbv) mixing ratios were associated with values of τss that exceeded 1 h for NO3 and 3 h for N2O5 near the ground. Such long boundary-layer lifetimes for NO3 and N2O5 are usually only encountered in very clean/unreactive air masses, whereas the PARADE measurement site is impacted by both biogenic emissions from the surrounding forest and anthropogenic emissions from the nearby urbanised/industrialised centres. Measurement of several trace gases which are reactive towards NO3 indicates that the inferred lifetimes are significantly longer than those calculated from the summed loss rate. Several potential causes for the apparently extended NO3 and N2O5 lifetimes are examined, including additional routes to formation of NO3 and the presence of a low-lying residual layer. Overall, the most likely cause of the anomalous lifetimes are related to the meteorological conditions, though additional NO3 formation due to reactions of Criegee intermediates may contribute.
Abstract. We report the characteristics and performance of a newly developed five-channel cavity ring-down spectrometer to detect NO3, N2O5, NO2, total peroxy nitrates (ΣPNs) and total alkyl nitrates (ΣANs). NO3 and NO2 are detected directly at 662 and 405 nm, respectively. N2O5 is measured as NO3 after thermal decomposition at 383 K. PNs and ANs are detected as NO2 after thermal decomposition at 448 and 648 K. We describe details of the instrument construction and operation as well as the results of extensive laboratory experiments that quantify the chemical and optical interferences that lead to biases in the measured mixing ratios, in particular involving the reactions of organic radical fragments following thermal dissociation of PNs and ANs. Finally, we present data obtained during the first field deployment of the instrument in July 2015.
Abstract. We describe the first instrument for measurement of the rate constant (s−1) for reactive loss (i.e., the total reactivity) of NO3 in ambient air. Cavity-ring-down spectroscopy is used to monitor the mixing ratio of synthetically generated NO3 ( ≈ 30–50 pptv) after passing through a flow-tube reactor with variable residence time (generally 10.5 s). The change in concentration of NO3 upon modulation of the bath gas between zero air and ambient air is used to derive its loss rate constant, which is then corrected for formation and decomposition of N2O5 via numerical simulation. The instrument is calibrated and characterized using known amounts of NO and NO2 and tested in the laboratory with an isoprene standard. The lowest reactivity that can be detected (defined by the stability of the NO3 source, instrumental parameters and NO2 mixing ratios) is 0.005 s−1. An automated dilution procedure enables measurement of NO3 reactivities up to 45 s−1, this upper limit being defined mainly by the dilution accuracy. The typical total uncertainty associated with the reactivity measurement at the center of its dynamic range is 16 %, though this is dependent on ambient NO2 levels. Results from the first successful deployment of the instrument at a forested mountain site with urban influence are shown and future developments outlined.
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