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Publikationstyp

Wissenschaftlicher Artikel

Erscheinungsjahr

2016
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Intercomparison of 15 aerodynamic particle size spectrometers (APS 3321): uncertainties in particle sizing and number size distribution

Autor:innen

Herausgeber

Quelle

Atmospheric Measurement Techniques
9 (2016), Heft 4

Schlagwörter

Finanzierungskennzeichen

standardisiertes Finanzierungskennzeichen

Verbundene Publikation

Zitation

Intercomparison of 15 aerodynamic particle size spectrometers (APS 3321): uncertainties in particle sizing and number size distribution, 2016. Atmospheric Measurement Techniques [online]. Bd. 9 (2016), Heft 4. DOI 10.60810/openumwelt-397. Verfügbar unter: https://openumwelt.de/handle/123456789/7083
Zusammenfassung englisch
Aerodynamic particle size spectrometers are a well-established method to measure number size distributions of coarse mode particles in the atmosphere. Quality assurance is essential for atmospheric observational aerosol networks to obtain comparable results with known uncertainties. In a laboratory study within the framework of ACTRIS (Aerosols, Clouds, and Trace gases Research Infrastructure Network), 15 aerodynamic particle size spectrometers (APS model 3321, TSI Inc., St. Paul, MN, USA) were compared with a focus on flow rates, particle sizing, and the unit-to-unit variability of the particle number size distribution. Flow rate deviations were relatively small (within a few percent), while the sizing accuracy was found to be within 10?% compared to polystyrene latex (PSL) reference particles. The unit-to-unit variability in terms of the particle number size distribution during this study was within 10?% to 20?% for particles in the range of 0.9 up to 3 Nano-m, which is acceptable for atmospheric measurements. For particles smaller than that, the variability increased up to 60?%, probably caused by differences in the counting efficiencies of individual units. Number size distribution data for particles smaller than 0.9?Ţm in aerodynamic diameter should only be used with caution. For particles larger than 3?Ţm, the unit-to-unit variability increased as well. A possible reason is an insufficient sizing accuracy in combination with a steeply sloping particle number size distribution and the increasing uncertainty due to decreasing counting. Particularly this uncertainty of the particle number size distribution must be considered if higher moments of the size distribution such as the particle volume or mass are calculated, which require the conversion of the aerodynamic diameter measured to a volume equivalent diameter. In order to perform a quantitative quality assurance, a traceable reference method for the particle number concentration in the size range 0.5-3 Nano-m is needed. Quelle: http://www.atmos-meas-tech.net