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Analyte organic

Molecular fluorescence and, to a lesser extent, phosphorescence have been used for the direct or indirect quantitative analysis of analytes in a variety of matrices. A direct quantitative analysis is feasible when the analyte s quantum yield for fluorescence or phosphorescence is favorable. When the analyte is not fluorescent or phosphorescent or when the quantum yield for fluorescence or phosphorescence is unfavorable, an indirect analysis may be feasible. One approach to an indirect analysis is to react the analyte with a reagent, forming a product with fluorescent properties. Another approach is to measure a decrease in fluorescence when the analyte is added to a solution containing a fluorescent molecule. A decrease in fluorescence is observed when the reaction between the analyte and the fluorescent species enhances radiationless deactivation, or produces a nonfluorescent product. The application of fluorescence and phosphorescence to inorganic and organic analytes is considered in this section. [Pg.429]

Organic Analytes As noted earlier, organic compounds containing aromatic rings generally are fluorescent, but aromatic heterocycles are often phosphorescent. Many important biochemical, pharmaceutical, and environmental compounds are aromatic and, therefore, can be analyzed quantitatively by fluorometry... [Pg.429]

Noncatalytic Reactions Chemical kinetic methods are not as common for the quantitative analysis of analytes in noncatalytic reactions. Because they lack the enhancement of reaction rate obtained when using a catalyst, noncatalytic methods generally are not used for the determination of analytes at low concentrations. Noncatalytic methods for analyzing inorganic analytes are usually based on a com-plexation reaction. One example was outlined in Example 13.4, in which the concentration of aluminum in serum was determined by the initial rate of formation of its complex with 2-hydroxy-1-naphthaldehyde p-methoxybenzoyl-hydrazone. ° The greatest number of noncatalytic methods, however, are for the quantitative analysis of organic analytes. For example, the insecticide methyl parathion has been determined by measuring its rate of hydrolysis in alkaline solutions. [Pg.638]

PROBLEMS OF DIRECTED FUNCTIONALIZATION OF ORGANIC ANALYTICAL REAGENTS... [Pg.402]

K.L. Cheng, K. Ueno, T. Imamura (Eds), CRC Handbook of Organic Analytical Reagents, CRC Press, Boca Raton, 1982. [Pg.50]

Organizes analytical laboratory paperwork sample log-in and tracking to final analysis reporting and invoicing, operates on singlc-CPU or local area network of IBM PC/XT/AT/80386 or compatible. [Pg.292]

Connors, K.A. Reaction Mechanisms in Organic Analytical Chemistry Wiley-Interscience New York, 1973. [Pg.15]

S. B. Hawthorne, D. J. Miller and M. S. Kiieger, Coupled SPE-GC a rapid and simple technique for excacting, identifying and quantitating organic analytes from solids and sorbent resins , 7. Chromatogr. Sci. 21 347-354 (1989). [Pg.248]

This section provides a brief review of a number of chelating and other extraction reagents, as well as some organic solvents, with special interest as to their selective extraction properties. The handbook of Cheng et al. should be consulted for a more detailed account of organic analytical reagents.11... [Pg.169]

Fisk JF. 1986. Semi-volatile organic analytical methods - general description and quality control considerations. In Perket CL, ed. Quality control in remedial site investigation Hazardous and industrial solid waste testing, ASTM Spec Tech Publ 925. Vol. 5, American Society for Testing and Materials, 143-156. [Pg.292]

Soxhlet extraction is probably the most widely used method for the extraction of organic analytes from solid samples. The... [Pg.387]

Applications The majority of SFE applications involves the extraction of dry solid matrices. Supercritical fluid extraction has demonstrated great utility for the extraction of organic analytes from a wide variety of solid matrices. The combination of fast extractions and easy solvent evaporation has resulted in numerous applications for SFE. Important areas of analytical SFE are environmental analysis (41 %), food analysis (38 %) and polymer characterisation (11%) [292], Determination of additives in polymers is considered attractive by SFE because (i) the SCF can more quickly permeate throughout the polymer matrix compared to conventional solvents, resulting in a rapid extraction (ii) the polymer matrix is (generally) not soluble in SCFs, so that polymer dissolution and subsequent precipitation are not necessary and (iii) organic solvents are not required, or are used only in very small quantities, reducing preparation time and disposal costs [359]. [Pg.95]

Another recently developed technique is headspace sorptive extraction (HSSE) with PDMS stir bars [552]. HSSE-GC was compared with SHS and HS-SPME. SBSE and HSSE extract organic analytes from aqueous or vapour samples. In SBSE, the stir bar is inserted into the aqueous sample and extraction takes place during stirring whereas in HSSE the glass rod is suspended within the headspace volume and sampling takes place during headspace equilibration. New trends are the development of selective sorbents. [Pg.133]

Although often used as a qualitative (identification) tool, MS may act as a quantitative inorganic mass detector. Quantification of organic analytes often takes place in combination with chromatography or in tandem MS mode. It should be realised that mass spectrometry is certainly not a panacea for all polymer/additive problems, although it is developing into a major tool for this purpose. [Pg.735]

The SPME process, adapted for solid or viscous matrix, is shown in Figure 10.1. A fused silica fibre, coated with a polymer, is installed inside a stainless steel hollow needle. In the first step, the needle is introduced in the sample vial through the septum. The fibre is then exposed to the headspace above the sample and the organic analytes adsorb to the coating of the fibre. After a variable sampling time, the fibre is drawn into the needle and the needle is withdrawn from the sample vial. Finally, in the same way, the fibre is introduced into the chromatograph injector where the analytes are thermally desorbed. [Pg.262]

The addition of water or the use of an aqueous solvent mixture is important for the extraction of other organic analytes from dry foodstuffs or dehydrated foods. It is particularly necessary in aiding the permeation of solvent through freeze-dried samples. [Pg.44]

See other pages where Analyte organic is mentioned: [Pg.254]    [Pg.346]    [Pg.430]    [Pg.520]    [Pg.217]    [Pg.341]    [Pg.377]    [Pg.438]    [Pg.903]    [Pg.40]    [Pg.317]    [Pg.286]    [Pg.429]    [Pg.603]    [Pg.388]    [Pg.907]    [Pg.53]    [Pg.105]    [Pg.110]    [Pg.129]    [Pg.272]    [Pg.449]    [Pg.307]    [Pg.1849]    [Pg.1850]    [Pg.93]    [Pg.343]    [Pg.382]    [Pg.582]   
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Organic analytes

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