Kinetics of the heterogeneous reaction of nitric acid with mineral dust particles: an aerosol flowtube study

The heterogeneous reaction of HNO3 with mineral dust aerosol (Arizona Test Dust) was studied in an aerosol flow tube at atmospherically relevant conditions (298 K, approximately 1 atm, 6-60% RH) and using radioactively labelled HNO3. The uptake of nitric acid was found to depend on HNO3 and H2O conc...

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Veröffentlicht in:	Physical chemistry chemical physics : PCCP 2009-01, Vol.11 (36), p.7921-7930
Hauptverfasser:	Vlasenko, A, Huthwelker, T, Gäggeler, H W, Ammann, M
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerosols - chemistry Atmosphere - analysis Atmosphere - chemistry Computer Simulation Dust - analysis Gases - chemistry Kinetics Minerals - chemistry Models, Chemical Particle Size Particulate Matter - chemistry Rheology - methods
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creator	Vlasenko, A Huthwelker, T Gäggeler, H W Ammann, M
description	The heterogeneous reaction of HNO3 with mineral dust aerosol (Arizona Test Dust) was studied in an aerosol flow tube at atmospherically relevant conditions (298 K, approximately 1 atm, 6-60% RH) and using radioactively labelled HNO3. The uptake of nitric acid was found to depend on HNO3 and H2O concentrations in the gas phase. A reaction mechanism is suggested to describe the heterogeneous interaction, involving Langmuir type adsorption and surface reaction. This mechanism is incorporated in a flux based aerosol kinetic model framework that is able to reproduce the observations within the range of experimental conditions. The experiments show that the reactive surface sites of the relatively calcium poor, but silicate rich dust surface are efficiently depleted at higher HNO3 concentrations in the gas phase or longer exposure times. A set of kinetic parameters is extracted from the data, which can be used to calculate uptake coefficients as function of time, concentration and humidity for use in atmospheric chemistry models to improve especially the representation of the effects of relative humidity on dust aging and to allow following dust aging with time.
doi_str_mv	10.1039/b904290n
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source	MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Aerosols - chemistry Atmosphere - analysis Atmosphere - chemistry Computer Simulation Dust - analysis Gases - chemistry Kinetics Minerals - chemistry Models, Chemical Particle Size Particulate Matter - chemistry Rheology - methods
title	Kinetics of the heterogeneous reaction of nitric acid with mineral dust particles: an aerosol flowtube study
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