The heterogeneous interaction of trace gases on mineral dust and soot : kinetics and mechanism

The present thesis work deals with the investigation of the heterogeneous reactions involving nitrate radical (NO3), dinitrogen pentoxide (N2O5) and ozone (O3) on surrogates of atmospheric mineral dust particles characteristic of the troposphere. An additional investigation of heterogeneous reaction of NO3 on flame soot was carried out. The goal is to characterize the kinetics (the uptake coefficient γ) as well as the reaction products. The obtained results are intended to provide reliable data for numerical modelling studies. The experiments were performed in a very low pressure flow reactor (Knudsen cell reactor), coupled to mass spectrometry (MS) and optical probing (Resonance Enhanced Multiphoton Ionization (REMPI)). The used mineral dust powder samples were: Kaolinite, CaCO3, natural limestone, Saharan Dust and Arizona Test Dust. Two different types of soot were produced: soot originating from a rich decane flame at a high fuel/oxygen ratio ("grey" soot) and soot generated from a lean flame at a low fuel/oxygen ratio ("black" soot). Uptake experiments of NO3 on mineral dust were carried out under continuous molecular flow conditions (steady state) at 298 ± 2 K using the thermal decomposition of N2O5 as a NO3 source. In situ laser detection (REMPI) was employed in addition to beam-sampling electron-impact mass spectrometry in order to specifically detect NO2 and NO in the presence of N2O5, NO3 and HNO3. We found a steady state uptake coefficient γss ranging from (3.4 ± 1.6) × 10-2 for natural limestone to 0.12 ± 0.08 for Saharan Dust with γss decreasing as [NO3] increased. NO3 adsorbed on mineral dust led to uptake of NO2 in an Eley-Rideal mechanism where usually no uptake is observed in the absence of NO3. The disappearance of NO3 was in part accompanied by the formation of N2O5 and HNO3 in the presence of NO2. NO3 uptake performed on small amounts of Kaolinite and CaCO3 led to formation of some N2O5 according to NO3(ads) + NO2(g) –> N2O5(ads) –> N2O5(g). Slow formation of gas phase HNO3 on Kaolinite, CaCO3, Arizona Test Dust and natural limestone has also been observed and is clearly related to the presence of adsorbed water involved in the heterogeneous hydrolysis of N2O5(ads). Uptake of N2O5 on mineral dust samples led to γss values ranging from (3.5 ± 1.1) × 10-2 for CaCO3 to 0.20 ± 0.05 for Saharan Dust with γss decreasing as [N2O5]0 increased. We have observed delayed production of HNO3 upon uptake of N2O5 for every investigated sample owing to hydrolysis of N2O5 with surface-adsorbed H2O. At high and low [N2O5] Arizona Test Dust and Kaolinite turned out to be the samples to produce the largest amount of gas phase HNO3 with respect to N2O5 taken up. In contrast, the yield of HNO3 for Saharan Dust and CaCO3 is lower. On CaCO3 the disappearance of N2O5 was also accompanied by the formation of CO2. For CaCO3 sample masses ranging from 0.33 to 2.0 g, the yield of CO2 was approximately 42 – 50% with respect to the total number of N2O5 molec