Stanovení rubidia ve vybraných rostlinných extraktech pomocí atomové absorpční spektrometrie / Determination of rubidium in selected plant extracts by atomic absorption spectrometry

Šatrová, Lucie

January 2019

In this diploma thesis, rubidium in plant material samples was determined by atomic absoption spectrometry. Determination of plant material rubidium was performed on two different atomic absorption spectrometers (GBC 933 AA and ContrAA 700) for comparison. The selection of a proper method of atomization was essential, therefore optimizations for the flame atomizer and electrothermal atomizer were performed. On the GBC 933 AA, flame atomization was tested. The flow rate of the acetylene-air, vertical and horizontal flame profile, spectral interval width was optimized for the instrument. On the ContrAA 700, the conditions for flame atomization were optimized as well as for electrothermal atomization. The optimized parameters included the acetylene-air flow rate and the vertical flame profile again. For the electrothermal atomization, the temperature dependence of pyrolysis and the temperature dependence of atomization were optimized. Under experimentally determined optimal conditions, the determination of rubidium in fruit and vegetable juice samples was performed by the method of calibration curve. Rubidium usually accompanies toher alkali metals. In the absence of essential biogenic elements iportant for plant growth, rubidium is able to help out and take on the role of potassium.

Lead Determination By Flame Atomic Absorption Spectrometry Using A Slotted Quartz Tube Atom Trap And Metal Coatings

Demirtas, Ilknur

01 July 2009

Flame Atomic Absorption Spectrometry (FAAS) still keeps its importance despite the relatively low sensitivity / because it is a simple and economical technique for determination of metals. In recent years atom traps have been developed to increase the sensitivity of FAAS. Although the detection limit of FAAS is only at the level of mg/L, with the use of atom traps it can reach to ng/mL. Slotted quartz tube (SQT) is one of these atom traps, it is applied for determination of volatile elements / it is economical, commercially available and easy to use. In this study, a sensitive analytical method has been developed for the determination of lead with the help of SQT. Regarding the angle between the two slots of SQT, 120&deg / and 180&deg / configurations were used and the results were compared. There were three modes of SQT used. The first application was for providing longer residence time of analyte atoms in the measurement zone / 3 fold sensitivity enhancement was observed. The second mode was the usage of SQT for preconcentration of lead atoms. In the presence of a lean air-acetylene flame, analyte atoms were trapped in the inner surface of SQT for a few minutes. Then, by the help of a small volume (10-50 &amp / #956 / L) of Methyl isobutyl ketone (MIBK), analyte atoms were revolatilized and a rapid atomization took place. Using this mode, a sensitivity enhancement of 574 was obtained at a rather low (3.9 mL/min) suction rate / 1320 fold improvement was reached at higher sample suction rate (7.4 mL/min) for 5.0 min collection. The last mode involves coating of the inner surface of SQT with several kinds of transition metals. The best sensitivity enhancement, 1650 fold, was obtained by the Ta coated SQT. In addition, effects of some elements and anions on Pb signal in Tacoated-SQT-AT-FAAS were examined. Final step consists of surface analysis / chemical nature of Pb trapped on quartz and Ta surface, and the chemical nature of Ta on quartz surface were investigated by X-ray Photoelectron Spectroscopy (XPS) and Raman Spectroscopy.

QD Analytical Chemistry 71-142

Tellurium Speciation Using Hydride Generation Atomic Absorption Spectrometry And In-situ Graphite Cuvette Trapping

Yildirim, Emrah

01 September 2009

In recent years speciation analysis is becoming more important as it is known that each chemical form of an element behaves differently in biological and environmental media. Since abundance of tellurium in earth crust is extremely low, very sensitive and accurate methods are needed to determine the concentration of tellurium. Hydride generation atomic absorption is a sensitive, fast and economical technique applied for the determination of tellurium. Speciation of tellurium can be achieved by making use of different kinetic behaviors of Te(IV) and Te(VI) upon its reaction with sodiumborohydride. A continuous flow hydride generation system was developed and parameters that affect the analytical signal were optimized. Sample solutions were prepared in 4.0 mol/L HCl / as reductant 0.5 % (w/v) sodiumborohydride in 0.5 % (w/v) NaOH was used. Quantitative reduction of Te(VI) was achieved through application of a microwave assisted prereduction of Te(VI) in 6.0 mol/L HCl solution. Sensitivity of the system was further enhanced by in-situ trapping of the formed H2Te species in a previously heated graphite furnace whose surface was modified using Pd or Ru. Overall efficiency of pyrolytic coated graphite surface was found to be 15% when hydrides are trapped for 60 seconds at 300 oC. LOD and LOQ values were calculated as 86 pg/mL and 287 pg/mL according to peak height values. Efficiency was increased by 46% and 36% when Pd and Ru modifiers were used, respectively. With Ru modified graphite tube 173 fold enhancement was obtained over 180 seconds trapping period with respect to direct ETAAS. LOD values were 6.4 and 2.2 pg/mL for Pd and Ru treated systems, respectively, for 180 s collection of 9.6 mL sample solution.

QD Analytical Chemistry 71-142

Determination Of Cadmium Using Slotted Quartz Tube Atom Trap Atomic Absorption Spectrometry And Metal Coatings

Ozcan Gurbetoglu, Pelin Gulistan

01 July 2010

ABSTRACT DETERMINATION OF CADMIUM USING SLOTTED QUARTZ TUBE ATOM TRAP ATOMIC ABSORPTION SPECTROMETRY AND METAL COATINGS &Ouml / zcan Gurbetoglu, G. Pelin M.S., Department of Chemistry Supervisor: Prof. Dr. O. Yavuz Ataman July 2010, 76 pages Flame atomic absorption spectroscopy (FAAS) is a common technique for detecting metals and metalloids in environmental, biological and metallurgical samples. Although it is a rather old technique, it is still very reliable, simple to use and inexpensive. The technique can be used to determine the concentration of over 70 different metals in a solution. However, it has detection limits at mg/L levels. Some atom trapping methods have been developed to reach the detection limits of ng/mL levels. Slotted quartz tube (SQT) is one of these atom trapping methods. It is an important technique, since it is easy to use, applicable in all laboratories, commercially available and economical. This thesis consists of development of a sensitive method for cadmium with the help of SQT atom trap. In this study, it was used for two different purposes. One was for keeping the analyte atoms more in the light path / in other words, for increasing the residence times of analyte atoms in the measurement zone. This first application was provided a 2.9 times enhancement with respect to conventional FAAS. Second application was for trapping the analyte on the surface of the SQT, in other words, for performing on-line preconcentration of cadmium in SQT. In the presence of a lean flame, analyte samples were trapped and collected for a few minutes at a low suction rate. After finishing the collection period, analyte atoms were revolatilized with the help of a small volume of (10-50 &micro / L) methyl isobutyl ketone (MIBK) and a rapid atomization occurred. This introduction also altered the flame composition momentarily and analyte atoms were released from the surface of the SQT. Application of this method enhanced the sensitivity 2065 times with respect to conventional FAAS. Another approach to this type of atom trapping has been investigated also in this study, which was coating of SQT with some metals having low volatility. Therefore, some transition metals were coated to the surface of SQT and among them zirconium was selected as the best coating material as having the most sensitivity enhancement factor. That is why, rest of the study was performed with the Zr coated SQT. The enhancement was 3368 as compared with FAAS. Cd determination with this method provides LOD value of 8 pg/mL and Co value of 19 pg/mL. In order to see the effect of some other type of elements or ions on determination of cadmium, interference study was done.

QD Analytical Chemistry 71-142

Tellurium Determination By Flame Atomic Absorption Spectrometry Using A Slotted Quartz Tube Atom Trap And Metal Coatings

Osmanbasoglu, Mahmut

01 February 2011

Flame Atomic Absorption Spectroscopy (FAAS) has lover sensitivity than similar analytical methods, however it has an important place for analysis due to its easy application and economic practicability especially in metal determinations. In order to increase the sensitivity of FAAS from mg/L level to ng/L level, various atom trap systems have been used. One of these atom traps, Slotted Quartz Tube (SQT), which is easy, economical and useful for volatile element determination, is used in this study as a sensitive analytical method for determination of tellurium. In the study, determination of Te by SQT is handled in three different modules. First, only with SQT itself, longer residence time for Te atoms in the measurement zone is provided and consequently 3.2 fold sensitivity enhancement is obtained both for Te (VI) and Te (IV). In the second module, SQT is used for concentration of tellurium species in a lean flame by sending the analyte into SQT for a definite time and trapping them on the inner surface of the SQT. After trapping the analyte, in order to determine the Te concentration, a small volume (10-50 &micro / L) of organic solvent such as methyl ethyl ketone (MEK) is introduced to the flame for revolatilization and a rapid atomization of Te on the surface is provided. In this trapping method, for 5 minutes collection with a 6 mL/min suction rate, 143 fold enhancement for Te (VI) and 142 fold enhancement for Te (IV) were obtained. In the third module, different from the second one, the inner surface of the SQT is coated with different metals for increasing the amount of Te trapped on the surface and the best enhancement for tellurium is obtained with Tantalum-coated SQT with 252 fold enhancement for Te (VI) and 246 fold enhancements for Te (IV). All improvements are calculated according to the signals obtained in FAAS method. Separate calibration plots were used for Te (IV) and Te (VI).

QD Analytical Chemistry 71-142

Determination Of Silver By Slotted Quartz Tube Atom Trap Flame Atomic Absorption Spectrometry Using Metalcoatings

Karaman, Gamze

01 September 2011

Silver is a precious metal having antibacterial property and widely used in industry mostly for water purification and medicinal products. Therefore, the determination of trace levels of silver is important for industrial applications. Flame atomic absorption spectrometry (FAAS) is a popular technique for the determination of relatively low concentration levels. This mature technique owes its widespread application to its simplicity and low cost. However, for some occasions, FAAS technique suffers from its low sensitivity because of low nebulization efficiency and relatively short residence time of analyte atoms in the measurement zone. In order to overcome this sensitivity problem, atom traps have been developed in recent years. Slotted quartz tube (SQT) is an accessory designed to use as an atom trap in conventional flame atomic absorption burner head. This thesis study involves the development of a sensitive, simple and economical technique with the help of the SQT for the determination silver. Firstly, the technique known as SQT-FAAS was used to increase the residence time of analyte atoms in the measurement zone. In this case, limit of detection (LOD) and characteristic concentration (C0) values were found to be 19 ng/mL and 35 ng/mL, respectively. Enhancement in sensitivity with respect to FAAS was found to be 2.31 fold using SQT-FAAS. Regarding the angle between the two slots of the SQT, 180&deg / configuration was used. Secondly, in order to improve sensitivity further, the SQT was used as an atom trap (AT) where the analyte is accumulated in its inner wall prior to re-atomization. The signal is formed after reatomization of analyte atoms on the trap surface by introduction of organic solvent. For this purpose, uncoated SQT was used as a trap medium. However, there was a memory effect. Therefore, the SQT inner surface was coated with different coating elements and theoptimum conditions were found by using W-coated SQT-AT-FAAS technique. In the presence of a lean air-acetylene flame, analyte atoms were trapped in the inner surface of the SQT for 5.0 min and then revolatilized with the introduction of 25 &mu / L isobutyl methyl ketone (IBMK) / afterwards, a transient signal was obtained. These optimized parameters were used for uncoated SQT, W-coated SQT and Zr-coated SQT atom trap techniques. Sample suction rate was 6.25 mL/min in all techniques. Sensitivity was increased 54 fold using uncoated SQT-AT-FAAS technique with respect to simple FAAS technique. When W-coated SQT-AT-FAAS technique was applied, 135 fold sensitivity enhancement was obtained with respect to FAAS technique. The best sensitivity enhancement, 270 fold, was obtained using Zr-coated SQT-AT-FAAS technique. In addition, the Ag signals were more reproducible (%RSD, 1.21) when Zr was used as a coating element. After the sensitive technique was developed, interference effects of some transition and noble metals and hydride forming elements on Ag signals were investigated. Finally, surface studies were done to determine the chemical state of Ag during trapping period by using X-ray Photoelectron Spectroscopy (XPS). It was observed that the Ag analyte is retained on the SQT surface in its oxide form.

QD Analytical Chemistry 71-142

On-line Preconcentration Of Vapor Forming Elements On Resistively Heated W-coil Prior To Their Determination By Atomic Absorption Spectrometry

Cankur, Oktay

01 May 2004

Vapor generation in atomic spectrometry is a well established technique for the determination of elements that can be volatilized by chemical reactions. In-situ trapping in graphite furnaces is nowadays one of the most popular methods to increase the sensitivity. In this study, resistively heated W-coil was used as an online trap for preconcentration and revolatilization of volatile species of Bi, Cd and Pb. The collected analyte species were revolatilized rapidly and sent to a quartz Ttube atomizer for AAS measurement. Although the nature of revolatilized species of Bi and Pb are not clear, they are probably molecular since they can be transported at least 45 cm without any significant decrease in the peak height values. However, cadmium is revolatilized from the trap surface as atoms. The experimental parameters were optimized for the highest vapor generation, trapping and revolatilization efficiencies. The concentration limits of detection calculated by the 3 of blank solution were found to be 0.0027, 0.0040 and 0.015 ng/mL for Bi (18 mL), Cd (4.2 mL) and Pb (2 mL), respectively / enhancement factors in the sensitivity were 130, 31 and 20, respectively. These values are comparable with those obtained by in-situ trapping in graphite furnaces or even ICP-MS found in the literature or better. Sensitivity can be improved further for Bi and Cd using larger sample volumes, but purification of blank is required for Pb. Certified standard reference materials were analyzed for the assessment of accuracy of developed method.

QD Analytical Chemistry 71-142

Determination Of Silver By Chemical Vapour Generation And Atomic Absorption Spectrometry

Ozturk, Cagla Pinar

01 September 2004

A method for determination of silver has been developed based on chemical vapour generation atomic absorption spectrometry (CVGAAS). Volatile species of silver in acidified medium were generated by the reduction of sodium tetrahydroborate / these species were sent to a flame-heated quartz tube atomizer (QTA) following isolation by using a gas-liquid separator. Flow injection (FI) was used for sample introduction. Optimization of parameters such as / concentrations of acid and NaBH4 concentration, flow rates of solutions and carrier gas were made. The influences of the well-known chemical modifier, Pd, and the effect of diethyldithiocarbomate (DDTC) were also examined. Interference study has been carried out for Ni(II), Co(II), Cu(II), Fe(III), Au(III), As(III), Pb(II), Se(IV) and Sn(II) . A detection limit of 7.5 ng mL-1 (n=11) was obtained with a 0.2 mL sample volume. With the FI-CVGAAS system 5.6 times sensitivity enhancement was achieved over flame atomic absorption spectrometry (FAAS).

QD Analytical Chemistry 71-142

Avaliação de aspectos configuracionais e analiticos da tecnica TSFFAAS / Evaluation of configurational and analytical aspects of the TSFFAAS technique

Brancalion, Marcel Luis, 1983-

15 December 2006

Orientadores: Marco Aurelio Zezzi Arruda, Edvaldo Sabadini / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-08T04:01:39Z (GMT). No. of bitstreams: 1 Brancalion_MarcelLuis_M.pdf: 4673350 bytes, checksum: c534cc09a6e535a7053d092d88633edf (MD5) Previous issue date: 2006 / Mestrado / Quimica Analitica / Mestre em Química

TS-FF-AAS

Spray térmico

Nebulização

Filmagem

Thermospray

Nebulization

Filming

Construção de um espectrômetro de absorção atômica e estudos de formação e evolução da nuvem atômica com atomização eletrotérmica em sistema de duplo filamento de tungstênio / Construction of an atomic absorption spectrometer and studies on the formation and evolution of the atomic cloud with electrothermal atomization in a double tungsten coil system

Jora, Manassés Zuliani, 1987-

25 August 2018

Orientadores: Celio Pasquini, Joaquim de Araújo Nóbrega / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-25T12:04:34Z (GMT). No. of bitstreams: 1 Jora_ManassesZuliani_M.pdf: 4929889 bytes, checksum: f8da5d6a35fbac5ae2d05d997971561a (MD5) Previous issue date: 2013 / Resumo: A espectrometria de absorção atômica com atomização eletrotérmica (ET AAS) é adequada para a determinação de metais e semimetais, apresentando alta sensibilidade. Dentre os atomizadores eletrotérmicos, os fornos de grafite destacam-se por sua boa seletividade, exigência de pequenos volumes de amostra e baixos limites de detecção (i.e. 'mu'g L-1). Porém, esses atomizadores requerem fontes de alta potência (i.e. superiores a 2 kW), sistema de resfriamento e, ainda, apresentam alto custo. Como alternativa, o uso de superfícies metálicas têm sido objeto de pesquisa desde 1970. Dentre todos os metais empregados na fabricação de superfícies metálicas e utilizados para os estudos em ET AAS, o tungstênio é o que vem apresentando maior aplicação. Porém, a espectrometria de absorção atômica baseada em atomizadores de filamento de tungstênio (WC AAS) apresenta vários desafios relacionados ao entendimento da geração da nuvem atômica e dos efeitos de interferência observados. Dessa maneira, neste trabalho construiu-se um espectrômetro de absorção atômica com duplo filamento de tungstênio (DWC AAS), com duas configurações, uma empregando como sistema de detecção um sistema echelle/detector de carga acoplada intensificado (ICCD) e outra um sistema filtro óptico-acústico sintonizável (AOTF)/fotomultiplicadora. Essas duas configurações do equipamento foram empregadas em estudos de formação e evolução da nuvem atômica de elementos com características voláteis e refratárias (i.e. Pb e Cr). Além disso, estudou-se o efeito de Na, K, Ca e Mg, em três diferentes concentrações (i.e. 1, 10 e 100 mg L-1) sobre os perfis das nuvens atômicas de Pb e Cr. Esse estudo foi conduzido de tal forma que interferências em fase condensada e gasosa puderam ser avaliadas. Além disso, o equipamento foi empregado em medidas de temperatura na superfície do filamento e na fase gasosa / Abstract: Electrothermal atomic absorption spectrometry (ET AAS) is suitable for determination of metals and semimetals with high sensitivity. Among the existing electrothermal atomizers, graphite furnace stands out due to its selectivity, requirement of low volume of sample and low limits of detection (i.e. 'mu'g L-1). Notwithstanding, these atomizers present high cost and requires high power power supply (i.e. above 2 kW) and a cooling system. Alternatively, metallic surfaces have been studied since 1970. Among all metals employed as atomizers in ET AAS studies, tungsten has presented the best results and has found many analytical applications. However, tungsten coil atomic absorption spectrometry (WC AAS) presents several challenges related to understanding the atomic cloud generation and interferences effects. Thus, in this work, a double tungsten coil atomic absorption spectrometer (DWC AAS), with two different configurations was constructed. In one configuration, a detection system based on echelle/intensified charge-coupled device (ICCD) is employed and, in the other, an acousto-optic tunable filter (AOTF)/photomultiplier detection system is used. Both configurations were employed in the atomic cloud generation and evolution studies of Pb and Cr. Furthermore, interferences on the atomic cloud profile of Pb and Cr caused by Na, K, Ca and Mg, at three different concentrations (i.e. 1, 10 and 100 mg L-1), were studied. This study helped to evaluate the effect of condensed and gas phase interferences. Additionally, the equipment was employed to perform measures of surface and gas phase temperatures / Mestrado / Quimica Analitica / Mestre em Química

Instrumentação analitica

Espectrometria de absorção atômica

Atomização eletrotérmica

Filamento de tungstênio

Analitical instrumentation

Atomic absorption spectrometry

Electrothermal atomization

Tungsten coil