High efficiency nebulization for helium inductively coupled plasma mass spectrometry

A pneumatically-driven, high efficiency nebulizer is explored for helium inductively coupled plasma mass spectrometry. The aerosol characteristics and analyte transport efficiencies of the high efficiency nebulizer for nebulization with helium are measured and compared to the results obtained with argon. Analytical performance indices of the helium inductively coupled plasma mass spectrometry are evaluated in terms of detection limits and precision. The helium inductively coupled plasma mass spectrometry detection limits obtained with the high efficiency nebulizer at 200 μL/min are higher than those achieved with the ultrasonic nebulizer consuming 2 mL/min solution, however, precision is generally better with high efficiency nebulizer (1–4% vs. 3–8% with ultrasonic nebulizer). Detection limits with the high efficiency nebulizer at 200 μL/min solution uptake rate approach those using ultrasonic nebulizer upon efficient desolvation with a heated spray chamber followed by a Peltier-cooled multipass condenser.     

Three-phase plasma arc atomic-emission spectrometric analysis of environmental samples using an ultrasonic nebulizer

Combination of an ultrasonic nebulizer and plasma excitation sources for spectrochemical analysis offers desirable features of low detection limits, high sample throughput, wide dynamic range of operation, acceptable precision and accuracy, and simultaneous quantitative analytical capabilities. Moreover, the ultrasonic nebulizer does not require sample preconcentration. Recently we have developed a three-phase plasma arc (TPPA) for atomic emission spectrochemical analysis. In the present work, to increase the analytical utility of the three-phase plasma system, an ultrasonic nebulizer was used for sample introduction. The effects of the argon gas flow rate, current, excitation temperature have been studied. The analytical calibration curves are obtained for Ca, Cr, Fe, Mg and Mn, and detection limits have been calculated. The present technique is used to determine the concentration of the elements Ca, Cr, Fe, Mg and Mn in airborne samples.     

Thermospray nebulizer as sample introduction technique for microwave plasma torch atomic emission spectrometry

A thermospray nebulizer was used as a sample introduction device for microwave plasma torch (MPT) atomic emission spectrometry (AES). Experimental parameters, including the power supplied to the MPT, the flow rates of support and carrier gases, the observation height, the sample uptake rate, the thermospray working temperature, the temperature of the aerosol spray chamber and cooling water were optimized. Under optimum conditions, the relative standard deviation (RSD) of 10 measurements for 21 elements is in the range 0.3–2.0%. The detection limits were improved in comparison with the ultrasonic nebulizer as sample introduction technique for MPT–AES. The inclusion of 20% methanol into the MPT showed there is no effect on the stability of MPT discharge. The technique can thus be held to have the potential for interface to reverse-phase HPLC systems.     

An assessment of an atmospheric pressure helium microwave plasma produced by a surfatron as an excitation source in atomic emission spectroscopy

A new microwave plasma at atmospheric pressure is described. The plasma is supported by a surface wave excitation structure called “surfatron”. Both argon and helium can be used to sustain the plasma. In this study, helium has been selected. The sample introduction system consists of an ultrasonic nebulizer associated with a dcsolvation system. The analytical performance in terms of detection limits, calibration curves and some interferences have been assessed. Because of the relatively low power and the short residence time the main problem seems to be the atomization process.     

An Ultrasonic Nebulizer as the Sample Introduction Device for High Performance Liquid Chromatography Combined with Inductively Coupled Plasma Atomic Emission Spectrometry

A preliminary study of an ultrasonic nebulizer as the sample introduction device for the chromatographic speciation of ionic compounds containing As, Se and Cr is described. The analytical figures of merit observed during chromatographic separations with an ultrasonic nebulizer interfaced to an inductively coupled plasma-atomic emission spectrometer (ICP-AES) were comparable to or better than conventional pneumatic nebulization and other sample introduction techniques, in terms of organic solvent tolerance, sensitivity, detection limits and reproducibility. The limits of detection were in the ranges of 10-14 ppb for Se, 30-40 ppb for As, and 8-10 ppb for Cr.     

Comparison of pneumatic and ultrasonic nebulizations in inductively coupled plasma atomic emission spectrometry — matrix effects and plasma parameters

Matrix effects and plasma parameters in inductively coupled plasma atomic emission spectrometry (ICP-AES) using the sample introduction systems with ultrasonic and pneumatic nebulizations were studied. Analytical line intensities of fourteen elements and their detection limits as well as plasma temperatures, electron number density and ion-to-atom line intensity ratios were investigated with and without presence of complex matrix composed of Na, K, Mg and Ca. With ultrasonic nebulization in comparison to pneumatic nebulization, the line intensities were enhanced and the enhancement factor was dependent on the total line excitation energy. For each type of the sample introduction system, the changes in line intensities induced by the complex matrix were correlated with the sum of Ca and Mg concentrations. The excitation temperatures of atoms and ions, the ionization temperatures and the ion-to-atom line intensity ratios were the lowest using the ultrasonic nebulizer and quite well comparable for both pneumatic nebulizers (Meinhard and V-groove). The differences between excitation temperatures of ions and atoms were the largest while the electron number density was the lowest when the ultrasonic nebulizer was employed. Generally, the plasma parameters were independent of the matrix composition. The differences in plasma parameters observed for the individual nebulizers were related to various amounts of solvent loaded to the plasma.     

Use of ultrasonic nebulizer with desolvator membrane for the determination of titanium and zirconium in human serum by means of inductively coupled plasma--mass spectroscopy

A technique for the determination of titanium and zirconium in human blood serum, after pressurized digestion utilizing ICP-MS coupled to an ultrasonic nebulizer (USN) and desolvating membrane is described. As no CRM for titanium is available, zirconium has been determined in order to demonstrate the accuracy of the technique, as the limits in blood are well known. Bone cement consists basically of a polymer, namely polymethylmethacrylate (PMMA). For better X-ray contrast some manufacturers use incorporated ZrO2 with a volume fraction of 10 to 15%. Thus, the zirconium present in the PMMA matrix can be used as an indicator for the PMMA particulate debris.     

Influence of RF power and nebulizer type on the intensity of the important cadmium lines in ICP spectroscopy

The authors studied the dependence of the net line intensity (x) on RF power (P) for three Cd lines with two different nebulizers a pneumatic and an ultrasonic nebulizer. The dependence of x on P was found to be different for the two nebulizer types and this difference is attributed to a difference in droplet size and a consequent difference in the rate of water introduction into the plasma associated with the two nebulizers.     

Studies of a radio frequency inductively coupled argon plasma for optical emission spectrometry—III. Interference effects under compromise conditions for simultaneous multi-element analysis

This work concerns interference effects in a 0.7-kW, 50-MHz inductively coupled plasma (ICP) provided with an ultrasonic nebulizer (USN) and desolvation apparatus (DA). The observations were made under (ICP) conditions adopted previously as “compromise conditions for simultaneous multi-element analysis.” Various matrices and analytes were considered.An arrangement of two identical USN's with separate DA's was used to distinguish between interferences due to processes in the plasma (“plasma effects”) and the nebulizer—desolvation apparatus (“nebulizer—desolvation effects”). The latter were identified as “desolvation effects” and attributed to a variation in the loss of analyte in the DA. This desolvation effect, whose magnitude varies between ±10%, is related to the difference in volatility between matrix and analyte. The experiments revealed plasma effects that cannot be reconciled with the common pictures of ionization interference and are not due to incomplete volatilization or dissociation either. Possible explanations are considered. The overall interference level in the ICP studied is discussed and practical conclusions regarding the use of desolvation, “pure” aqueous solutions as standards, and spectroscopic buffers are drawn.     

Use of ultrasonic nebulizer with desolvator membrane for the determination of titanium and zirconium in human serum by means of inductively coupled plasma – mass spectroscopy

A technique for the determination of titanium and zirconium in human blood serum, after pressurized digestion utilizing ICP-MS coupled to an ultrasonic nebulizer (USN) and desolvating membrane is described. As no CRM for titanium is available, zirconium has been determined in order to demonstrate the accuracy of the technique, as the limits in blood are well known. Bone cement consists basically of a polymer, namely polymethylmethacrylate (PMMA). For better X-ray contrast some manufacturers use incorporated ZrO₂ with a volume fraction of 10 to 15%. Thus, the zirconium present in the PMMA matrix can be used as an indicator for the PMMA particulate debris.