Application of experimental design for optimization of erbium determination by high-resolution continuum source electrothermal atomic absorption spectrometry using lanthanum as a chemical modifier

References

• Shankar, S.; Pathmanathan, P. K. C. Novel Usage of Erbium in Optical Communication Systems: From Fundamentals to Performance Characteristics. Media and Communications- Technologies, Policies and Challenges. Nova Science Publishers: New York, USA, 2010.
   Google Scholar
• Banner, A. Chemistry and Applications of Argon, Erbium, Radium, Berkelium and Californium; Library Press: Delhi, India, 2012.
   Google Scholar
• Chumakova, N. L.; Smirnova, E. V. Determination of lanthanum, cerium, neodymium, ytterbium, and yttrium in geological samples with the use of a multichannel analyzer of atomic emission spectra. Inorganic Materials 2011, 47(14), 1522–1528.
   Web of Science ®Google Scholar
• Silva, J. S. A., et al. Determination of rare earth elements in spent catalyst samples from oil refinery by dynamic reaction cell inductively coupled plasma mass spectrometry. Journal of the Brazilian Chemical Society 2014, 25(6), 1062–1070.
   Web of Science ®Google Scholar
• Liu, Y., et al. Determination of trace and rare-earth elements in Chinese soil and clay reference materials by ICP-MS. Chinese Journal of Geochemistry 2014, 33(1), 95–102.
   Google Scholar
• Shaltout, A. A., et al. Determination of rare earth elements in dust deposited on tree leaves from Greater Cairo using inductively coupled plasma mass spectrometry. Environmental Pollution 2013, 178, 197–201.
   PubMed Web of Science ®Google Scholar
• Kumar, S. A.; Pandey, S. P.; Kumar, S. D. Determination of rare earth elements in Indian kimberlite using inductively coupled plasma mass spectrometer (ICP-MS). Journal of Radioanalytical and Nuclear Chemistry 2012, 294(3), 419–424.
   Web of Science ®Google Scholar
• Xu, Y., et al. Determination of trace amounts of rare-earth elements in clean steel by inductively coupled plasma optical emission spectrometry after removal of iron matrix with anion-exchange resin. Applied Spectroscopy 2010, 64(5), 543–546.
   PubMed Web of Science ®Google Scholar
• Bentlin, F. R.S.; Pozebon, D. Direct determination of lanthanides in environmental samples using ultrasonic nebulization and ICP OES. Journal of the Brazilian Chemical Society 2010, 21(4), 627–634.
   Web of Science ®Google Scholar
• Lopez-Molinero, A.; Villareal, A.; Anzano, J. Erbium determination in preforms of optical fibres by inductively coupled plasma-atomic emission spectrometry. Talanta, 1992, 39(2), 191–193.
   PubMed Web of Science ®Google Scholar
• Li, X. L.; Zhang, Q. Determination of fifteen rare earth elements in soil, stream sediment and rock samples by X-ray fluorescence spectrometry with pressed powder pellet. Yejin Fenxi/Metallurgical Analysis 2013, 33(7), 35–40.
   Google Scholar
• Sitko, R., Zawisza, B.; Czaja, M. Fundamental parameters method for determination of rare earth elements in apatites by wavelength-dispersive X-ray fluorescence spectrometry. Journal of Analytical Atomic Spectrometry 2005, 20(8), 741–745.
   Web of Science ®Google Scholar
• Dybczyński, R. S., et al. Comparison of performance of INAA, RNAA and ion chromatography for the determination of individual lanthanides. Applied Radiation and Isotopes 2010, 68(1), 23–27.
   PubMed Web of Science ®Google Scholar
• Danko, B.; Dybczyński, R. S.; Samczyński, Z. Accurate determination of individual lanthanides in biological materials by NAA with pre-and post-irradiation separation. Journal of Radioanalytical and Nuclear Chemistry 2008, 278(1), 81–88.
   Web of Science ®Google Scholar
• Oddone, M.; Meloni, S.; Genova, N. Neutron activation analysis: A powerful tool for assay of rare-earth elements in terrestrial materials. Inorganica Chimica Acta, 1984, 94(6), 283–290.
   Web of Science ®Google Scholar
• Yi-zai, M.; Jian, B.; Di-jun, S. Determination of erbium by electrothermal atomic absorption spectrometry using a pyrolytic graphite coated graphite tube and a pyrolytic graphite coated graphite tube lined with tantalum foil, held in place by a tungsten spiral. Journal of Analytical Atomic Spectrometry 1992, 7(1), 35–42.
   Web of Science ®Google Scholar
• Sastry, M. D., et al. Electrothermal AAS studies of Sm, Eu, Dy, and Er separated from uranium. Fresenius’ Zeitschrift für Analytische Chemie 1979, 298(5), 367–372.
   Google Scholar
• Gupta, J. G.S. Determination of yttrium and rare-earth elements in rocks by graphite-furnace atomic-absorption spectrometry. Talanta 1981, 28(1), 31–36.
   PubMed Web of Science ®Google Scholar
• Sicińska, P.; Michalewska, M. Application of atomic absorption spectrophotometry for the determination of lanthanides in ores and rare earth concentrates. Fresenius’ Zeitschrift für Analytische Chemie, 1982, 312(6), 530–532.
   Google Scholar
• Sen Gupta, J. G. Determination of lanthanides and yttrium in rocks and minerals by atomic-absorption and flame-emission spectrometry. Talanta 1976, 23(5), 343–348.
   PubMed Web of Science ®Google Scholar
• Bencs, L.; Szakács, O.; Kántor, T. Determination of erbium and neodymium dopants in bismuth tellurite optical crystals by graphite furnace atomic spectrometry techniques. Spectrochimica Acta, Part B: Atomic Spectroscopy, 1999, 54(8), 1193–1206.
   Web of Science ®Google Scholar
• Kumar, P., et al. Determination of lanthanides and yttrium in high purity dysprosium by rp-hplc using δ-hydroxyisobutyric acid as an eluent. Journal of Liquid Chromatography and Related Technologies 2013, 36(11), 1513–1527.
   Web of Science ®Google Scholar
• Santoyo, E., Guevara, M.; Verma, S. P. Determination of lanthanides in international geochemical reference materials by reversed-phase high-performance liquid chromatography using error propagation theory to estimate total analysis uncertainties. Journal of Chromatography A 2006, 1118(1), 73–81.
   PubMed Web of Science ®Google Scholar
• Nekoei, M., Zamani, H. A.; Mohammadhossieni, M. Erbium(III) PVC membrane ion-selective sensor based on 4-(2-Thiazolylazo) resorcinal. Analytical Letters 2009, 42(2), 284–297.
   Web of Science ®Google Scholar
• Ganjali, M. R., et al. Novel erbium (III)-selective fluorimetric bulk optode. Sensors and Actuators, B: Chemical, 2009, 142(1), 90–96.
   Web of Science ®Google Scholar
• Zamani, H. A.; Faridbod, F. Selective determination of erbium in the mixture of other lanthanide ions by a potentiometric sensor. Sensor Letters 2013, 11(3), 571–575.
   Google Scholar
• Singh, A.; Singh, S.; Singh, G. Comparative study of poly(vinyl chloride) based polymeric membrane sensors for the determination of erbium (III). Analytical and Bioanalytical Electrochemistry 2012, 4(3), 296–314.
   Google Scholar
• Mirshafian, R.; Norouzi, P.; Ganjali, M. R. Voltammetric ion-selective nanocomposite carbon paste electrode for determination of erbium at the interface between two immiscible electrolyte solutions. Electroanalysis 2012, 24(2), 433–438.
   Web of Science ®Google Scholar
• Zamani, H. A., et al. Determination of erbium ions in water samples by a pvc membrane erbium-ion selective electrode. Sensor Letters 2010, 8(2), 303–307.
   Google Scholar
• Gorbatenko, A. A.; Revina, E. I. A review of instrumental methods for determination of rare earth elements. Inorganic Materials 2015, 51(14), 1375–1388.
   Web of Science ®Google Scholar
• Zawisza, B., et al. Determination of rare earth elements by spectroscopic techniques: A review. Journal of Analytical Atomic Spectrometry 2011, 26(12), 2373–2390.
   Web of Science ®Google Scholar
• Prasada Rao, T.; Biju, V. M. Trace determination of lanthanides in metallurgical, environmental, and geological samples. Critical Reviews in Analytical Chemistry 2000, 30(2–3), 179–220.
   Web of Science ®Google Scholar
• Verma, S. P.; Santoyo, E. High-performance liquid and ion chromatography: Separation and quantification analytical techniques for rare earth elements. Geostandards and Geoanalytical Research 2007, 31(3), 161–184.
   Web of Science ®Google Scholar
• Resano, M.; García-Ruiz, E. High-resolution continuum source graphite furnace atomic absorption spectrometry: Is it as good as it sounds? A critical review. Analytical and Bioanalytical Chemistry 2011, 399(1), 323–330.
   PubMed Web of Science ®Google Scholar
• Shaltout, A. A.; Welz, B.; Castilho, I. N. B. Determinations of Sb and Mo in Cairo's dust using high-resolution continuum source graphite furnace atomic absorption spectrometry and direct solid sample analysis. Atmospheric Environment 2013, 81, 18–24.
   Web of Science ®Google Scholar
• Dittert, I. M., et al. Simultaneous determination of cobalt and vanadium in undiluted crude oil using high-resolution continuum source graphite furnace atomic absorption spectrometry. Journal of Analytical Atomic Spectrometry 2010, 25(4), 590–595.
   Web of Science ®Google Scholar
• De Babos, D. V., et al. Cobalt internal standard for Ni to assist the simultaneous determination of Mo and Ni in plant materials by high-resolution continuum source graphite furnace atomic absorption spectrometry employing direct solid sample analysis. Talanta 2016, 152, 457–462.
   PubMed Web of Science ®Google Scholar
• Lepri, F. G., et al. Speciation analysis of volatile and non-volatile vanadium compounds in Brazilian crude oils using high-resolution continuum source graphite furnace atomic absorption spectrometry. Analytica Chimica Acta 2006, 558(1–2), 195–200.
   Web of Science ®Google Scholar
• Colares, L., et al. Application of disposable starch-based platforms for sample introduction and determination of refractory elements using graphite furnace atomic absorption spectrometry and direct solid sample analysis. Journal of Analytical Atomic Spectrometry 2015, 30(2), 381–388.
   Web of Science ®Google Scholar
• Virgilio, A., et al. Determination of Cd, Ni and V in spices by solid sampling high-resolution continuum source graphite furnace atomic absorption spectrometry. Journal of the Brazilian Chemical Society 2015, 26(10), 1988–1993.
   Web of Science ®Google Scholar
• Lara, P. C. P., et al. Use of multivariate optimization to develop methods for direct copper and lead determination in breast milk by graphite furnace atomic absorption spectrometry. Food Analytical Methods 2014, 7(4), 790–797.
   Web of Science ®Google Scholar
• El Ati-Hellal, M.; Hellal, F.; Hedhili, A. Application of Plackett-Burman and Doehlert designs for optimization of selenium analysis in plasma with electrothermal atomic absorption spectrometry. Clinical Biochemistry 2014, 47(15), 95–100.
   PubMed Web of Science ®Google Scholar
• Soares, A. R.; Nascentes, C. C. Simple method for determination of lead in hair dyes using slurry sampling graphite furnace atomic absorption spectrometry. Analytical Letters 2012, 46(2), 356–366.
   Web of Science ®Google Scholar
• Fabrino, H. J. F., et al. Multivariate approach in the optimization procedures for the direct determination of manganese in serum samples by graphite furnace atomic absorption spectrometry. Journal of Analytical Toxicology 2011, 35(8), 571–576.
   PubMed Web of Science ®Google Scholar
• Lara, P. C. P., et al. Direct determination of Mn in breast milk by GF AAS after multivariate optimization. Analytical Letters 2009, 42(7), 923–934.
   Web of Science ®Google Scholar
• Arambarri, I., Garcia, R.; Millán, E. Application of experimental design in a method for screening sediments for global determination of organic tin by electrothermal atomic absorption spectrometry (ETAAS). Analytical and Bioanalytical Chemistry 2001, 371(7), 955–960.
   Web of Science ®Google Scholar