Emission, sensitized, identification

The classical wet-chemical quaUtative identification of chromium is accompHshed by the intense red-violet color that develops when aqueous Cr(VI) reacts with (5)-diphenylcarba2ide under acidic conditions (95). This test is sensitive to 0.003 ppm Cr, and the reagent is also useful for quantitative analysis of trace quantities of Cr (96). Instmmental quaUtative identification is possible using inductively coupled argon plasma—atomic emission spectroscopy... 

Luminescence spectroscopy is one of the most sensitive techniques for identification of impurities in dyes. The most commonly observed impurities in to-bipyridyl complexes of the type [RuL2X2] are the homoleptic tris-bipyridyl species [RuL3]2+. Since the emission quantum yields of the [RuL3]2+ complexes are significantly higher than those of the [RuL2X2] complexes, one can identify the homoleptic impurities at a level of less than 1%. This does depend, however, on the relative quantum yields, and position of the emission spectral maxima, for the complexes and impurities involved. 

Molecular fluorescence involves the emission of radiation as excited electrons return to the ground state. The wavelengths of the radiation emitted are different from those absorbed and are useful in the identification of a molecule. The intensity of the emitted radiation can be used in quantitative methods and the wavelength of maximum emission can be used qualitatively. A considerable number of compounds demonstrate fluorescence and it provides the basis of a very sensitive method of quantitation. Fluorescent compounds often contain multiple conjugated bond systems with the associated delocalized pi electrons, and the presence of electron-donating groups, such as amine and hydroxyl, increase the possibility of fluorescence. Most molecules that fluoresce have rigid, planar structures. 

Deep state experiments measure carrier capture or emission rates, processes that are not sensitive to the microscopic structure (such as chemical composition, symmetry, or spin) of the defect. Therefore, the various techniques for analysis of deep states can at best only show a correlation with a particular impurity when used in conjunction with doping experiments. A definitive, unambiguous assignment is impossible without the aid of other experiments, such as high-resolution absorption or luminescence spectroscopy, or electron paramagnetic resonance (EPR). Unfortunately, these techniques are usually inapplicable to most deep levels. However, when absorption or luminescence lines are detectable and sharp, the symmetry of a defect can be deduced from Zeeman or stress experiments (see, for example, Ozeki et al. 1979b). In certain cases the energy of a transition is sensitive to the isotopic mass of an impurity, and use of isotopically enriched dopants can yield a positive chemical identification of a level. 

The discussion in Section II-B indicates that optical emission from 02(1E 7+) or 02(1A9) to the ground state may provide a useful method for the identification and estimation of the excited species. In laboratory studies, the (0, 0) bands, lying at about 7620 A and 1.27 [x, respectively, are likely to be the strongest. The emission at 7620 A is relatively easily detected by suitable photomultipliers, and spectra may even be recorded with photographic emulsions sensitive to the near infrared (such as the Kodak N coating). Trialkali (S20) photocathodes combine a high sensitivity with low dark current, and photomultipliers with an S20 cathode... 

The recent identification of selective protease substrates to simultaneously measure markers of both viable and dead cells led to the development of optional methods for HTS that provide flexibility and added advantages (Niles et al. 2007a). The assay to measure viable cells is based on a cell-permeable protease substrate called glycyl-phenylalanyl-aminofluorocoumarin (GF-AFC). The procedure is a homogeneous add-incubate-measure method that is faster, more sensitive, and less toxic to cells than the tetrazolium and resazurin reduction assays. The substrate can be prepared in an aqueous buffer and is added directly to samples containing cells. The substrate permeates viable cells where constitutive protease activity in the cytoplasm rapidly removes the amino acids, yielding free AFC. The amount of AFC released is directly proportional to viable cell numbers and shows improved sensitivity compared to the resazurin assay (Figure 6.5). The AFC is detected via a microplate fluo-rometer equipped with a (380- to 400-nm excitation/505-nm emission) filter set. 

Spectroscopic detectors measure partial or complete energy absorption, energy emission, or mass spectra in real-time as analytes are separated on a chromatography column. Spectroscopic data provide the strongest evidence to support the identifications of analytes. However, depending on the spectroscopic technique, other method attributes such as sensitivity and peak area measurement accuracy may be reduced compared to some nonselective and selective detectors. The mass spectrometer and Fourier transform infrared spectrometer are examples of spectroscopic detectors used online with GC and HPLC. The diode array detector, which can measure the UV-VIS spectra of eluting analytes is a... 

The application of PIXE (Proton Induced X-Ray Emission) and micro-PIXE to quantitative analysis of impurities in polyethylene are described. The equipment, sources of background which affect the sensitivity and the precision of PIXE measurements are discussed for both thick and thin targets. A number of applications of micro-PIXE to the identification and location of trace elements in the "Trees" found in the polymer insulation of HV cables are presented. 

---