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By atomic spectroscopy

Tungsten is usually identified by atomic spectroscopy. Using optical emission spectroscopy, tungsten in ores can be detected at concentrations of 0.05—0.1%, whereas x-ray spectroscopy detects 0.5—1.0%. ScheeHte in rock formations can be identified by its luminescence under ultraviolet excitation. In a wet-chemical identification method, the ore is fired with sodium carbonate and then treated with hydrochloric acid addition of 2inc, aluminum, or tin produces a beautiful blue color if tungsten is present. [Pg.284]

The performance of microwave-assisted decomposition of most difficult samples of organic and inorganic natures in combination with the microwave-assisted solution preconcentration is illustrated by sample preparation of carbon-containing matrices followed by atomic spectroscopy determination of noble metals. Microwave-assisted extraction of most dangerous contaminants, in particular, pesticides and polycyclic aromatic hydrocarbons, from soils have been developed and successfully used in combination with polarization fluoroimmunoassay (FPIA) and fluorescence detection. [Pg.245]

Elemental analysis can be performed at ultratrace levels with any atomic spectrometric technique and the final selection is based on the identity and the number of elements to be determined. The initial step that is common to all analyses by atomic spectroscopy is the generation of a homogeneous solution. [Pg.247]

The selection of a technique to determine the concentration of a given element is often based on the availability of the instrumentation and the personal preferences of the analytical chemist. As a general rule, AAS is preferred when quantifications of only a few elements are required since it is easy to operate and is relatively inexpensive. A comparison of the detection limits that can be obtained by atomic spectroscopy with various atom reservoirs is contained in Table 8.1. These data show the advantages of individual techniques and also the improvements in detection limits that can be obtained with different atom reservoirs. [Pg.248]

The quantification of ultratrace elements by atomic spectroscopy should be performed on the basis of the addition of a series of known concentrations of the element(s) to the sample and quantifications are... [Pg.250]

On the basis of the preceding discussion, it should be obvious that ultratrace elemental analysis can be performed without any major problems by atomic spectroscopy. A major disadvantage with elemental analysis is that it does not provide information on element speciation. Speciation has major significance since it can define whether the element can become bioavailable. For example, complexed iron will be metabolized more readily than unbound iron and the measure of total iron in the sample will not discriminate between the available and nonavailable forms. There are many other similar examples and analytical procedures that must be developed which will enable elemental speciation to be performed. Liquid chromatographic procedures (either ion-exchange, ion-pair, liquid-solid, or liquid-liquid chromatography) are the best methods to speciate samples since they can separate solutes on the basis of a number of parameters. Chromatographic separation can be used as part of the sample preparation step and the column effluent can be monitored with atomic spectroscopy. This mode of operation combines the excellent separation characteristics with the element selectivity of atomic spectroscopy. AAS with a flame as the atom reservoir or AES with an inductively coupled plasma have been used successfully to speciate various ultratrace elements. [Pg.251]

P is called promotion energy. The configuration of the free atoms as in the metal is usually an excited state of the atom hence, the promotion energy can be usually obtained by atomic spectroscopy results. [Pg.90]

Characteristic Masses for Identification of Additional Organic Pollutants (Not Listed in the Text) by GC/MS Volatility of Some Additional Organic Substances (Not Listed in Text) for Purge and Trap Analysis Analysis of Elements by Atomic Spectroscopy ... [Pg.6]

APPENDIX G ANALYSIS OF ELEMENTS BY ATOMIC SPECTROSCOPY AN OVERVIEW... [Pg.432]

Analysis of Elements by Atomic Spectroscopy An Overview (Continued)... [Pg.433]

During the 20-plus years that mass spectrometrists lost interest in glow discharges, optical spectroscopists were pursuing these devices both as line sources for atomic absorption spectroscopy and as direct analytical emission sources [6-10]. Traditionally, inorganic elemental analysis has been dominated by atomic spectroscopy. Since an optical spectrum is composed of lines corre-... [Pg.32]

C. Hardaway, J. Sneddon, J. N. Beck, Determination of metals in crude oil by atomic spectroscopy, A mini-review, Anal. Lett., 37 (2004), 1-19. [Pg.452]

J. Sneddon, M. G. Heagler, Determination of mercury by atomic spectroscopy application to fish, Advances in Atomic Spectroscopy, 4 (1998), 213-229. [Pg.453]

Hoenig, M., de Kersabiec, A.-M. Sample preparation steps for analysis by atomic spectroscopy methods present status. Spectrochim. Acta Part B 51, 1297-1307 (1996)... [Pg.115]

The selectivity and sensitivity offered by atomic spectroscopy techniques can be used for direct and indirect determination of metals in a range of pharmaceutical preparations and compounds. Metals can be present in pharmaceutical preparations as a main ingredient, impurities, or as preservatives which can be prepared for analysis using non-destructive (direct or solvent dilution) or destructive methods (microwave acid digestion, bomb combustion, extraction, etc.) and the metal of interest measured against standards of the metal prepared in the same solvents as the sample. Methods associated with some pharmaceutical products are already described in the international pharmacopoeias and must be used in order to comply with regulations associated with these products, e.g titration techniques are carried out according to methods that are the same for all pharmaceutical products. [Pg.230]

In most cases the determination of organometallic complexes by atomic spectroscopy techniques is the only acceptable method because the analysis is selective, accurate and precise. Analysis of these complex salts may only involve a simple dilution in a solvent or destruction methods depending on the matrix it is formulated into. The presence of some sample matrices containing organometallic complexes can be severely restricted by the matrix material to achieve accurate detection and quantification of these salts. [Pg.237]

Detection Limits (ng/mL) for Some Elements by Atomic Spectroscopy ... [Pg.864]

Sodium and potassium levels are difficult to analyze by titrimetric or colorimetric techniques but are among the elements most easily determined by atomic spectroscopy (2,38) (Table 2). Their analysis is important for the control of infusion and dialysis solutions, which must be carefully monitored to maintain proper electrolyte balance. Flame emission spectroscopy is the simplest and least expensive technique for this purpose, although the precision of the measurement may be improved by employing atomic absorption spectroscopy. Both methods are approved by the U.S. (39), British (40), and European (41) Pharmacopeias and are commonly utilized. Sensitivity is of no concern, due to the high concentrations in these solutions furthermore, dilution of the sample is often necessary in order to reduce the metal concentrations to the range where linear instmmental response can be achieved. Fortunately, the analysis may be carried but without additional sample preparation because other components, such as dextrose, do not interfere. [Pg.434]

CONTENTS 1. Basic Principles (J. W. Robinson). 2. Instrumental Requirements and Optimisation (J. E. Cantle). 3. Practical Techniques (J. E. Cantle). 4a. Water and Effluents (B. J. Farey and L A. Nelson). 4b. Marine Analysis by AAS (H. Haraguchi and K. Fuwa). 4c. Analysis of Airborne Particles in the Workplace and Ambient Atmospheres (T.J. Kneip and M. T. Kleinman). 4d. Application of AAS to the Analysis of Foodstuffs (M. Ihnat). 4e. Applications of AAS in Ferrous Metallurgy (K. Ohis and D. Sommer). 4f. The Analysis of Non-ferrous Metals by AAS (F.J. Bano). 4g. Atomic Absorption Methods in Applied Geochemistry (M. Thompson and S. J. Wood). 4h. Applications of AAS in the Petroleum Industry W. C. Campbell). 4i. Methods forthe Analysis of Glasses and Ceramics by Atomic Spectroscopy (W. M. Wise et al.). 4j. Clinical Applications of Flame Techniques (B.E. Walker). 4k. Elemental Analysis of Body Fluids and Tissues by Electrothermal Atomisation and AAS (H. T. Delves). 4I. Forensic Science (U. Dale). 4m. Fine, Industrial and Other Chemicals. Subject Index. (All chapters begin with an Introduction and end with References.)... [Pg.316]

Hetland S, Martinsen I, Radzuk B and Tho-massen Y (1991) Species analysis of inorganic compounds in workroom air by atomic spectroscopy. Anal Sci 7 1029-1034. [Pg.1670]

Atomic spectroscopic methods have an enormous advantage in their speed. The final determination of a single element by atomic spectroscopy can be made in a minute or less. Most voltammetric determinations take five minutes or more for the potential scan alone. However the situation can be reversed for multi-element determinations. Polarographic or voltammetric methods often allow the simultaneous determination of several species in the same solution. With the atomic spectroscopic methods each element would require a change of lamp and its realignment. [Pg.204]

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See also in sourсe #XX -- [ Pg.269 , Pg.270 , Pg.272 ]



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