Avaliação de estratégias analíticas para reduzir interferências em ICP-MS e ICP OES
Abstract
Inductively Coupled Plasma Mass Spectrometry (ICP-MS) and Inductively Coupled Plasma Optical Emission Spectrometry (ICP OES) are widely multi-element techniques used to analysis complex samples. Otherwise some aspects, such as spectral interferences and low transport efficiency due to pneumatic nebulization limit their applications. In this work the use of the collision-reaction interface (CRI) of ICP-MS in sequential extraction of the As, Cd, Cr, Cu, Pb, V and Zn in sample of soil treated with vinasse for removal of polyatomic interferences and online hydride generation using a Flow Blurring® multinebulizer for the elimination of matrix interferences and improvement of transport efficiency in determining the As, Sb, Se and Sn by ICP OES have been evaluated. In the evaluation of the CRI, it was found that the flow rates of 60 mL min-1 of H2 and 80 mL min-1 of He introduced into the skimmer cone were the flow rates that showed better efficiency in the correction of interferences and was necessary to perform the inorganic matrix matching (majoritarian elements) of the calibration curve and blanks. The sequential extraction of soil samples treated with vinasse showed that the addition this residue contributes to the increase in the concentration of Cu in exchangeable fraction. The proposed method for hydride generation uses an integrated system, in which the formation of volatile species occurs by interaction of aerosols generated by the different multinebulizer orifices in the ICP-OES spray chamber, without the need of any special system. To this end, two of the three multinebulizer orifices are used to continuously nebulize acid and reducing agent, respectively, while the third one is used to sample introduction. The system was optimized to obtain the highest sensitivity using factorial designs. Interference effects of transition metals were corrected by addition of thiourea. The accuracy of the method was verified by determination of antimony, arsenic, selenium and tin in standard reference materials.