Abstract
Stability of airborne nanoparticle agglomerates is important for occupational exposure and risk assessment in determining particle size distribution of nanomaterials. In this study, we developed an integrated method to test the stability of aerosols created using different types of nanomaterials. An aerosolization method, that resembles an industrial fluidized bed process, was used to aerosolize dry nanopowders. We produced aerosols with stable particle number concentrations and size distributions, which was important for the characterization of the aerosols׳ properties. Next, in order to test their potential for deagglomeration, a critical orifice was used to apply a range of shear forces to them. The mean particle size of tested aerosols became smaller, whereas the total number of particles generated grew. The fraction of particles in the lower size range increased, and the fraction in the upper size range decreased. The reproducibility and repeatability of the results were good. Transmission electron microscopy imaging showed that most of the nanoparticles were still agglomerated after passing through the orifice. However, primary particle geometry was very different. These results are encouraging for the use of our system for routine tests of the deagglomeration potential of nanomaterials. Furthermore, the particle concentrations and small quantities of raw materials used suggested that our system might also be able to serve as an alternative method to test dustiness in existing processes.
Highlights
Increasing number of products based on nanotechnology are leading to an increasing potential for human exposure to nanomaterials in the workplace
An orifice-based approach was used to study the deagglomeration potential of airborne nanomaterials using a wide range of air turbulence levels induced by the pressure drop across the critical orifice
The results show that the system managed to deliver a stable aerosolization process
Summary
Increasing number of products based on nanotechnology are leading to an increasing potential for human exposure to nanomaterials in the workplace. The inhalation of nanomaterials poses potential health risks (Bourdon et al, 2013; Paur et al, 2011). Particle sizes and their state of agglomeration determine where they deposit in the lung structure (Rissler et al, 2012; Zhang & Kleinstreuer, 2011). Nanoparticles deposited in lungs could by-pass their defense system and enter the circulatory system, which could adversely affect the n Corresponding author at: Institute for Work and Health (IST), Universities of Lausanne and Geneva, Route de la Corniche 2, CH-1066 Epalinges, Switzerland.
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