Influence of the type of working electrode on the limit of detection in voltammetric procedures for the determination of In(III) in environmental water sample

Pole DC	Wartość	Język
dc.contributor.author	Grabarczyk, Małgorzata	-
dc.date.accessioned	2024-11-29T12:01:45Z	-
dc.date.available	2024-11-29T12:01:45Z	-
dc.date.issued	2021	-
dc.identifier.citation	Modern problems and solutions in environmental protection - 2021. Post-conference monograph, edited by Urszula Czyżewska, Marek Bartoszewicz, Róża Sawczuk, Białystok 2021, s. 50-58	pl
dc.identifier.isbn	978-83-7431-692-7	-
dc.identifier.uri	http://hdl.handle.net/11320/17667	-
dc.description.abstract	Three simple and fast adsorptive stripping voltammetric procedures for trace determination of indium in environmental water samples were described. For all indium ion determination procedures, cupferron was used for the first time as a complexing agent. However, these procedures differed in the key element, which is the working electrode, which largely determines the detection limit and range of quantification. The following working electrodes were used in the research: a mercury film electrode with a silver substrate (Hg(Ag)FE), a lead film electrode (PbFE) and a bismuth film electrode (BiFE) . The influence of humic substances and foreign ions on the voltammetric indium Signal was examined in all procedures, which allowed for the evaluation of their practical application for direct analysis of environmental water samples. Finally, the developed procedures were used for analysis of certified reference materials: waste water and surface water, as well as natural waters taken from the Lublin region: from the Bystrzyca river and the Zemborzycki Lake.	pl
dc.language.iso	en	pl
dc.publisher	University of Bialystok Press	pl
dc.subject	mercury film electrode	pl
dc.subject	lead film electrode	pl
dc.subject	bismuth film electrode	pl
dc.subject	humic substances	pl
dc.title	Influence of the type of working electrode on the limit of detection in voltammetric procedures for the determination of In(III) in environmental water sample	pl
dc.type	Book chapter	pl
dc.rights.holder	© Copyright by Uniwersytet w Białymstoku, Białystok 2021	pl
dc.description.Affiliation	Department of Analytical Chemistry and Instrumental Analysis, Faculty of Chemistry, Maria Curie-Sklodowska University M.C. Sklodowska sq. 3, 20-031 Lublin (Poland)	pl
dc.description.references	Alfantazi AM., Moskalyk R.R. (2003) Processing of indium: a review Minerals Engineering 16: 687-694.	pl
dc.description.references	Craig J.R., Vaughan D.J., Skinner B.J. (2001 ) Resources of the earth: Origin, Use and Environmental Impact, Third Edition, Prentice Hall.	pl
dc.description.references	Merian E., Anke M., Ihnat M., Stoeppler H. (2004) Elements and their Compounds in the Environment. 2nd edition, Viley- VCH Verlag GmbH&Co. KGaA, Weinheim.	pl
dc.description.references	National Toxicology Program, Chemical lnformation Profil for Indium Tin Oxide, U.S. Department of Health and Human Services, 2009.	pl
dc.description.references	Tanaka A., Hirata M., Kiyohara Y., Omae K., Shiratani M., Koga K. (2010) Review of pulmonary tOxicity of indium compounds to animals and humans. Thin Solid Films 518: 2934-2936.	pl
dc.description.references	Paolicchi I., Dorrunguez O., Lomillo M.A.A, Martinez M.J.A. (2004) Application of an optimization procedure in adsorptive stripping voltammetry for the determination of trace contaminant metals in aqueous medium. Analytica Chimica Acta 511: 223-229.	pl
dc.description.references	Benvidi A., Ardakani M.M. (2009) Subnanomolar Determination of Indium by Adsorpti ve Stripping Differential Pulse Voltammetry Using Factorial Design for Optimization. Analytical Letters 42: 2430-2443.	pl
dc.description.references	Farias P.A.M., Martins C.M.L., Ohara A.K., Gold J.S., (1994) Cathodic adsorptive stripping voltammetry of indium complexed with morin at a static mercury drop electrode. Analytiea Chimica Acta 293: 29-34.	pl
dc.description.references	Grabarczyk M., Koper A. (2011) Direct determination of cadmium traces in natural water by adsorptive stripping voltammetry in the presence of cupferron as a chelating agent. Electroanalysis 24: 33-36.	pl
dc.description.references	Grabarczyk M., Wardak C. (2014) A new voltammetrie strategy for sensitive and selective determination of gallium using cupferron as a complexing agent. Journal of Environmental Science and Health, Part A 49: 1142-1148.	pl
dc.description.references	Adamczyk M., Grabarczyk M. (2020) Combination of PbFE as an electrochemical sensor and cupferron as a complexing agent for the rapid determination of Mo(VI). lonics 26: 3513-3521.	pl
dc.description.references	Grabarczyk M., Wasąg J. (2016a) Ultra trace determination of indium in natural water by adsorptive stripping voltammetry in the presence of cupferron as a complexing agent. Journal of the Electrochemical Society 163: H218-H222.	pl
dc.description.references	Grabarczyk M., Wasąg J. (2016b) Application of a lead film electrode in adsorptive stripping voltammetry for the determination of indium trace in water samples. Journal of the Electrochemical Society 163 (2016) H465-H468.	pl
dc.description.references	Wasąg J., Grabarczyk M. (2016) Adsorptive stripping voltammetry of In(III) in the presence of cupferron using an in situ plated bismuth film electrode. Analytical Methods 8: 3605-3612.	pl
dc.description.firstpage	50	pl
dc.description.lastpage	58	pl
dc.identifier.citation2	Modern problems and solutions in environmental protection - 2021. Post-conference monograph, edited by Urszula Czyżewska, Marek Bartoszewicz, Róża Sawczuk	pl
dc.conference	XVI Międzynarodowa Interdyscyplinarna Konferencja „Current Environmental Issues – 2021”, Białystok 22-24 września 2021 r.	pl
Występuje w kolekcji(ach):	Książki / Rozdziały (WUwB) XVI Międzynarodowa Interdyscyplinarna Konferencja „Current Environmental Issues-2021”, 22-24 września 2021

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