Counting on chemistry: laboratory evaluation of seed-material-dependent detection efficiencies of ultrafine condensation particle counters

Condensation particle counters (CPCs) are crucial instruments for detecting sub-10 nm aerosol particles. Understanding the detection performance of a CPC requires thorough characterization under well-controlled laboratory conditions. Besides the size of the seed particles, chemical interactions betw...

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Bibliographic Details
Published in:Atmospheric measurement techniques 2020-07, Vol.13 (7), p.3787-3798
Main Authors: Wlasits, Peter Josef, Stolzenburg, Dominik, Tauber, Christian, Brilke, Sophia, Schmitt, Sebastian Harald, Winkler, Paul Martin, Wimmer, Daniela
Format: Article
Language:English
Subjects:
Aerosol particles
Analysis
Butanol
Caryophyllene
Charged particles
Chemical fingerprinting
Chemical interactions
Condensates
Condensation
Condensers
Condensers (liquefiers)
Detection
Detection equipment
Detectors
Diameters
Diethylene glycol
Efficiency
Fluids
Instruments
Laboratories
Nucleation
Nucleation processes
Oxidation
Particle counters
Profiles
Radiation counters
Seeds
Supersaturation
Ultrafines
Vapors
Working fluids
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Summary:Condensation particle counters (CPCs) are crucial instruments for detecting sub-10 nm aerosol particles. Understanding the detection performance of a CPC requires thorough characterization under well-controlled laboratory conditions. Besides the size of the seed particles, chemical interactions between the working fluid and the seed particles also influence the activation efficiencies. However, common seed particle materials used for CPC characterizations are not chosen with respect to chemical interactions with vapor molecules of the working fluid by default. Here, we present experiments on the influence of the seed particle material on the detection efficiencies and the 50 % cutoff diameters of commonly used CPCs for the detection of sub-10 nm particles. A remarkable set consisting of six different and commercially available particle detectors, including the newly developed TSI V-WCPC 3789 and a tuned TSI 3776, was tested. The corresponding working fluids of the instruments are n-butanol, diethylene glycol and water. Among other materials we were able to measure detection efficiencies with nanometer-sized organic seed particles reproducibly generated by the oxidation of β-caryophyllene vapor in a flow tube. Theoretical simulations of supersaturation profiles in the condensers were successfully related to measured detection efficiencies. Our results demonstrate the importance of chemical similarities between seed particles and the working fluids used when CPCs are characterized. We anticipate our study to contribute to a deeper understanding of chemical interactions during heterogeneous nucleation processes.
ISSN:1867-8548
1867-1381
1867-8548
DOI:10.5194/amt-13-3787-2020