Number concentrations of fine and ultrafine particles containing metals

Typical classification schemes for large data sets of single-particle mass spectra involve statistical or neural network analysis. In this work, a new approach is evaluated in which particle spectra are pre-selected on the basis of an above threshold signal intensity at a specified m/ z (mass to cha...

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Bibliographic Details
Published in:Atmospheric environment (1994) 2004-06, Vol.38 (20), p.3263-3273
Main Authors: Tolocka, Michael P., Lake, Derek A., Johnston, Murray V., Wexler, Anthony S.
Format: Article
Language:English
Subjects:
Ambient aerosol
Chemical composition
Metals
Particle number concentration
Real-time single-particle mass spectrometry
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Summary:Typical classification schemes for large data sets of single-particle mass spectra involve statistical or neural network analysis. In this work, a new approach is evaluated in which particle spectra are pre-selected on the basis of an above threshold signal intensity at a specified m/ z (mass to charge ratio). This provides a simple way to identify candidate particles that may contain the specific chemical component associated with that m/ z. Once selected, the candidate particle spectra are then classified by the fast adaptive resonance algorithm, ART 2-a, to confirm the presence of the targeted component in the particle and to study the intra-particle associations with other chemical components. This approach is used to characterize metals in a 75,000 particle data set obtained in Baltimore, Maryland. Particles containing a specific metal are identified and then used to determine the size distribution, number concentration, time/wind dependencies and intra-particle correlations with other metals. Four representative elements are considered in this study: vanadium, iron, arsenic and lead. Number concentrations of ambient particles containing these elements can exceed 10,000 particles cm −3 at the measurement site. Vanadium, a primary marker for fuel oil combustion, is observed from all wind directions during this time period. Iron and lead are observed from the east–northeast. Most particles from this direction that contain iron also contain lead and most particles that contain lead also contain iron, suggesting a common emission source for the two. Arsenic and lead are observed from the south–southeast. Particles from this direction contain either arsenic or lead but rarely both, suggesting different sources for each element.
ISSN:1352-2310
1873-2844
DOI:10.1016/j.atmosenv.2004.03.010