Dynamics and mass accommodation of HCl molecules on sulfuric acid-water surfaces

A molecular beam technique has been used to study the dynamics and mass accommodation of HCl molecules in collision with sulfuric acid-water surfaces. The experiments were performed by directing a nearly mono-energetic beam of HCl molecules onto a continuously renewed liquid film of 54-76 wt% sulfur...

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Veröffentlicht in:	Physical chemistry chemical physics : PCCP 2009-01, Vol.11 (36), p.8048-8055
Hauptverfasser:	Behr, P, Scharfenort, U, Ataya, K, Zellner, R
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerosols - chemistry Atmosphere - chemistry Gases - chemistry Hydrochloric Acid - chemistry Kinetics Models, Chemical Particle Size Particulate Matter - chemistry Sulfuric Acids - chemistry Surface Properties
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creator	Behr, P Scharfenort, U Ataya, K Zellner, R
description	A molecular beam technique has been used to study the dynamics and mass accommodation of HCl molecules in collision with sulfuric acid-water surfaces. The experiments were performed by directing a nearly mono-energetic beam of HCl molecules onto a continuously renewed liquid film of 54-76 wt% sulfuric acid at temperatures between 213 K and 243 K. Deuterated sulfuric acid was used to separate sticking but non-reactive collisions from those that involved penetration through the phase boundary followed by dissociation and recombination with D+. The results indicate that the mass accommodation of HCl on sulfuric acid-water surfaces decreases sharply with increasing acidity over the concentration range 54-76 wt%. Using the capillary wave theory of mass accommodation this effect is explained by a change of the surface dynamics. Regarding the temperature dependence it is found that the mass accommodation of HCl increases with increasing temperature and is limited by the bulk phase viscosity and driven by the restoring forces of the surface tension. These findings imply that under atmospheric conditions the uptake of HCl from the gas phase depends crucially on the bulk phase parameters of the sulfuric acid aerosol.
doi_str_mv	10.1039/b904629a
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source	MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Aerosols - chemistry Atmosphere - chemistry Gases - chemistry Hydrochloric Acid - chemistry Kinetics Models, Chemical Particle Size Particulate Matter - chemistry Sulfuric Acids - chemistry Surface Properties
title	Dynamics and mass accommodation of HCl molecules on sulfuric acid-water surfaces
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