@article{25070, keywords = {Gas, USA, Emission, Power, Plasma diagnostics, Diagnostics, Ions, Ablation, Laser, Laser ablation, Laser ablation, Spectroscopy, Intensities, Intensity, Time, Ion, Ca, E, Element, Inductively coupled plasma (icp), Inductively-coupled plasma, Matrix, Nebulization, Plasma, Sample, Spectrometry, Emission spectroscopy, Emission spectroscopy, Icp, Line, Ratio, Science, C, England, Mechanism, Matrix effects, Argon, Argon plasma, Calcium, Carrier gas, Charge-exchange, Easily ionizable elements, Elements, Emission spectrometry, Emission spectrometry, Excitation, Ga, Helium, Interference, Interference mechanism, Interferences, Ionization, Lecture, Line-intensities, Magnesium, Matrices, Matrix effect, Mixed-gas plasma, Mixture, Ratios, Sample introduction, Solution, Solution nebulization, Zinc}, author = {George C.Y Chan and Wing-Tat Chan and Xianglei Mao and Richard E Russo}, title = {Investigation of matrix effects in inductively coupled plasma-atomic emission spectroscopy using laser ablation and solution nebulization - effect of second ionization potential}, abstract = {
Plasma-related non-spectroscopic matrix effects of 31 elements in inductively coupled plasma (ICP)-atomic emission spectrometry were investigated using both laser ablation and solution nebulization as sample introduction techniques. Matrix effects were studied by monitoring the excitation conditions of the plasma using the ionic to atomic spectral line intensity ratios of zinc and magnesium. A new kind of matrix interference was found in the ICP that appears to be related to matrices with elements of low second ionization potential. The matrix effects do not correlate with the first ionization potential of the element. Only those matrix elements with low second ionization potential showed severe matrix effects. Increasing the forward power of the ICP or replacing the carrier gas with a 50%/50% argon-helium mixture did not significantly reduce this matrix effect. However, using 100% helium as the carrier gas greatly reduced the extent of this matrix effect, suggesting that argon is involved in the interference mechanism. The interference mechanism may involve interactions between doubly-charged matrix ions and argon species. (C) 2001 Elsevier Science B.V. All rights reserved
}, year = {2001}, journal = {Spectrochimica Acta Part B-Atomic Spectroscopy}, volume = {56}, pages = {77-92}, note = {LBNL-47088 NOT IN FILE
}, language = {eng}, }