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Sample introduction electrothermal vaporization

Fig. 1.6 Automation of the first few stages (preliminary operations) of the analytical process (Type 2 analyser). Automatic system for Introduction of samples In electrothermal-vaporization atomic absorption spectroscopy. Fig. 1.6 Automation of the first few stages (preliminary operations) of the analytical process (Type 2 analyser). Automatic system for Introduction of samples In electrothermal-vaporization atomic absorption spectroscopy.
Modifications and variants on AA include multielement lamps and alternative thermal excitation methods, such as furnaces. Graphite furnace AA utilizes a small graphite cell for sample introduction and heating. The sample is placed on a shelf called the L vov platform inside the furnace (Figure 5.42). Graphite conducts, so when current is applied, the furnace rapidly heats and volatilizes the sample via electrothermal vaporization. A graphite furnace uses much less sample than a flame and allows for finer control of temperature. [Pg.176]

Moens L, Verreft P, Boonen S, Vanhaecke F and Dams R (1995) Solid sampling electrothermal vaporization for sample introduction in inductively coupled plasma atomic emission spectrometry and inductively coupled plasma mass spectrometry. Spectrochim Acta 508 463-475. Mooijman KA, In t Veld PH, Hoekstra JA, Heisterkamp SH, Havelaar AH, Notermans SHW, Roberts D, Griepink B, Maier E (1992) Development of Microbiological Reference Materials. European Commission Report EUR 14375 EN, Community Bureau of Reference, Brussels. [Pg.46]

Bjorn E, Freeh W, Hoffmann E, Liidke C (1998) Investigation and quantification of spectroscopic interferences from polyatomic species in inductively coupled plasma mass spectrometry using electrothermal vaporization or pneumatic nebulization for sample introduction. Spectrochim Acta 53B 1766... [Pg.237]

SAMPLE INTRODUCTION INTO ICP-AES ORICP-MS BY ELECTROTHERMAL VAPORIZATION... [Pg.159]

Gunn et al. [44] described the apphcation of a graphite-filament electrothermal vaporization apparatus as a sample introduction system for optical emission spectroscopy with an inductively coupled argon plasma source. Good detection levels were reported for the elements, and details of the interfacing requirements between the ICP and the graphite filament were explored. [Pg.160]

Volume 1 consists of chapters covering the development. Instrumentation, and results of a wide range of materials, including background correction lasers, inductively coupled-mass sp>ectroscopy plasmas, electrothermal vaporizers, sample introduction, and Fourier transform atomic spectrocopy. [Pg.268]

Alternate Sample Introduction — Obviously, elimination of the sample dissolution stage would greatly reduce analytical time, as it is the slowest step in the analytical scheme. Pulsed-laser vaporization using a CO2—TEA laser seems promising(63, 64). Another possibility is the introduction of a suitable prepared slurry of the sample into the nebullzer(65). Thermal vaporization studies using heated substrates such as tanta-lum(66), carbon filaments(67), or carbon rods(39) have been reported. Silvester(39) de fined the problems of vapor transport, carrier gas expansion, and solid phase chemistry associated with electrothermal sample introduction to an ICP. [Pg.130]

Because of its capability for rapid multielement analysis, ICP-MS is particularly suited to sample introduction methods which give rise to transient signals. For example, electrothermal vaporization, flow injection and chromatographic methods can be interfaced and many elements monitored in a single run (see Chapter 7). [Pg.131]

Various efficient devices have been utilized for sample introduction into an inductive plasma source, for example the application of several nebulizers, hyphenated techniques, hydride generation, laser ablation and electrothermal vaporization. The role of the solution introduction system in an inductively coupled plasma source is to convert the liquid sample into a suitable form (e.g.,... [Pg.37]

The role of the sample introduction system is to convert a sample into a form that can be effectively vaporized into free atoms and ions in the ICP. A peristaltic pump is typically used to deliver a constant flow or sample solution (independent of variations in solution viscosity) to the nebulizer. Several different kinds of nebulizers are available to generate the sample aerosol, and several different spray chamber designs have been used to modify the aerosol before it enters the ICP Gases can be directly introduced into the plasma, for example, after hydride generation. Solids can be introduced by using electrothermal vaporization or laser ablation. [Pg.73]

Mixed Gas Plasmas. Water loading can be reduced by a desolvation system (condenser or membrane separator) only if the vast majority of the water can be removed. One way to eliminate the introduction of water into the plasma during measurement of the analyte signals is with electrothermal vaporization, laser ablation, or other direct solid sampling techniques. Mixed gas plasmas,... [Pg.106]

Electrothermal vaporization has also been used for seawater sample introduction into an ICP-MS. Trace metals were complexed and then vaporized as dithiocarbamate complexes in one study [322]. Addition of a matrix modifier [Pd(N03)2-Mg(N03) ] enhanced analyte sensitivity. Addition of a matrix modifier to act as a physical carrier in ETV-ICP-MS has become common. Seawater was used as a matrix modifier for ETV-ICP-MS in one report [323]. [Pg.134]

Impurities in photoresists have also been measured by ICP-MS [383,384]. Ultrasonic nebulization and electrothermal vaporization sample introduction approaches have been used. [Pg.139]


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See also in sourсe #XX -- [ Pg.87 ]

See also in sourсe #XX -- [ Pg.36 , Pg.46 , Pg.54 , Pg.80 , Pg.90 ]




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