Thibaut Durand, Sébastien Bau, Yves Morele, Virginie Matera, Denis Bémer, Davy Rousset

  • Department of Metrology, French National Institute of Occupational Safety and Health (INRS), 1 Rue du Morvan, Vandoeuvre, 54519, France

Received: October 2, 2013
Revised: April 2, 2014
Accepted: May 19, 2014
Download Citation: ||https://doi.org/10.4209/aaqr.2013.10.0304  

  • Download: PDF


Cite this article:
Durand, T., Bau, S., Morele, Y., Matera, V., Bémer, D. and Rousset, D. (2014). Quantification of Low Pressure Impactor Wall Deposits during Zinc Nanoparticle Sampling. Aerosol Air Qual. Res. 14: 1812-1821. https://doi.org/10.4209/aaqr.2013.10.0304


HIGHLIGHTS

  • Chemical quantification of Dekati® low pressure impactor wall deposits.
  • Tested aerosol representative of thermal processes emissions.
  • Precise localization of wall losses among the different parts of the impactor.

 

ABSTRACT


A Dekati® low pressure impactor (DLPI) is used to determine the mass distribution of airborne particles from 7 nm to 10 µm as a function of aerodynamic diameter. Quantification of wall deposits inside this sampling device was performed for the first time using polydisperse zinc aerosol produced by a thermal spraying process. This aerosol is more representative of the size distribution found in occupational atmospheres than aerosols usually produced in laboratories. Each experiment (3 replicates) was carried out for two durations. The results showed that wall deposits were quite considerable and in relation with aerosol modes. 13% and 14% of the total mass was found on the wall after sampling periods of 5 and 20 minutes, respectively. Relative losses could reach 50% for certain impaction stages and these losses were also quite different between replicates.


Keywords: Dekati® low pressure impactor; Wall loss; Polydisperse aerosol; Zinc nanoparticles; Chemical analysis

Don't forget to share this article 

 

Subscribe to our Newsletter 

Aerosol and Air Quality Research has published over 2,000 peer-reviewed articles. Enter your email address to receive latest updates and research articles to your inbox every second week.