Main content area

Room Temperature Cation Exchange Reaction in Nanocrystals for Ultrasensitive Speciation Analysis of Silver Ions and Silver Nanoparticles

Huang, Ke, Xu, Kailai, Tang, Jie, Yang, Lu, Zhou, Jingrong, Hou, Xiandeng, Zheng, Chengbin
Analytical chemistry 2015 v.87 no.13 pp. 6584-6591
Paramecium, ambient temperature, analytical methods, cadmium, cation exchange, detection limit, fluorescence, ions, mixing, nanocrystals, nanosilver, silver, sodium, spectrometers, statistical analysis, toxicity, vapors
To evaluate the toxicity of silver nanoparticles (AgNPs) and Ag⁺ and gain deep insight into the transformation of AgNPs in the environment or organisms, ultrasensitive analytical methods are needed for their speciation analysis. About 40-fold of Cd²⁺ in CdTe ionic nanocrystals can be “bombarded-and-exploded” (exchanged) in less than 1 min simply by mixing the nanocrystals with Ag⁺ solution at room temperature, while this cation exchange reaction did not occur when only silver nanoparticles were present. On the basis of this striking difference, an ultrasensitive method was developed for speciation analysis of Ag⁺ and AgNPs in complex matrices. The released Cd²⁺ was reduced to its volatile species by sodium tetrahydroborate, which was separated and swept to an inductively coupled plasma mass spectrometer (ICPMS) or an atomic fluorescence spectrometer (AFS) for the indirect but ultrasensitive detection of Ag⁺. Owing to the remarkable signal amplification via the cation exchange reaction and the advantages of chemical vapor generation for sampling, the limit of detection was 0.0003 μg L–¹ for Ag⁺ by ICPMS, which was improved by 100-fold compared to the conventional method. Relative standard deviations are better than 2.5% at a concentration of 0.5 μg L–¹ Ag⁺ or AgNPs regardless of the detector. The proposed method retains several unique advantages, including ultrahigh sensitivity, speciation analysis, simplicity and being organic reagent-free, and has been successfully utilized for speciation analysis of Ag⁺ and AgNPs in environmental water samples and paramecium cells.