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Results of an interlaboratory comparison for characterization of Pt nanoparticles using single-particle ICP-TOFMS.

Lyndsey HendriksRobert BrünjesSara TaskulaJovana KocicBodo HattendorfGarret BlandGregory LowryEduardo Bolea-FernandezFrank VanhaeckeJingjing WangMohammed A BaaloushaMarcus von der AuBjörn MeermannTimothy Ronald HolbrookStephan WagnerStasia HaryckiAlexander Gundlach-GrahamFrank von der Kammer
Published in: Nanoscale (2023)
This study describes an interlaboratory comparison (ILC) among nine (9) laboratories to evaluate and validate the standard operation procedure (SOP) for single-particle (sp) ICP-TOFMS developed within the context of the Horizon 2020 project ACEnano. The ILC was based on the characterization of two different Pt nanoparticle (NP) suspensions in terms of particle mass, particle number concentration, and isotopic composition. The two Pt NP suspensions were measured using icpTOF instruments (TOFWERK AG, Switzerland). Two Pt NP samples were characterized and mass equivalent spherical sizes (MESSs) of 40.4 ± 7 nm and 58.8 ± 8 nm were obtained, respectively. MESSs showed <16% relative standard deviation (RSD) among all participating labs and <4% RSD after exclusion of the two outliers. A good agreement was achieved between the different participating laboratories regarding particle mass, but the particle number concentration results were more scattered, with <53% RSD among all laboratories, which is consistent with results from previous ILC studies conducted using ICP-MS instrumentation equipped with a sequential mass spectrometer. Additionally, the capabilities of sp-ICP-TOFMS to determine masses on a particle basis are discussed with respect to the potential for particle density determination. Finally, because quasi-simultaneous multi-isotope and multi-element determinations are a strength of ICP-TOFMS instrumentation, the precision and trueness of isotope ratio determinations were assessed. The average of 1000 measured particles yielded a precision of below ±1% for intensity ratios of the most abundant Pt isotopes, i.e. 194 Pt and 195 Pt, while the accuracy of isotope ratios with the lower abundant isotopes was limited by counting statistics.
Keyphrases
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