Inorganic extender detection

In addition to organic pigment analysis, XRD is used extensively for the analysis of inorganic crystalline compounds. Thus, inorganic extenders such as clay, barium sulfate, titanium dioxide, and other crystalline salts that could be present in commercial pigments are easily detectable by XRD. 

This protocol was extended to other inorganic colloids (e.g., ZnS, PbS), and it was pointed out that such extension paves the way to an electrochemical coding technology for the simultaneous detection of multiple DNA targets based on nanocrystal tags with diverse redox potentials [148]. 

Applications Applications of IC extend beyond the measurement of anions and cations that initially contributed to the success of the technique. Polar organic and inorganic species can also be measured. Ion chromatography can profitably be used for the analysis of ionic degradation products. For example, IC permits determination of the elemental composition of additives in polymers from the products of pyrolysis or oxidative thermal degradation. The lower detection limit for additives in polymers are 0.1% by PyGC... 

Since the early 1990s an increasing number of papers has been devoted to the application of CE for the analysis of both inorganic cations [906-915] and low-molecular-mass anions [915-922]. Standard CE methods have been developed and validated for determining inorganic anions (e.g. chloride, sulfate and nitrate), small carboxylic acids and metal ions that all have limited or no UV absorbance. In those situations, short UV wavelengths (190 nm) or indirect UV detection should be used. Such methods might be extended to metallic... 

All these advances have resulted not only in increases in resolution but have also alleviated the detection problems to a considerable extent. As a result, the last decade has seen a dramatic growth in 15N- and 170-NMR spectroscopy as a versatile method for studying molecular structure, both in isotropic (liquid) and anisotropic (solid) phases. Studies at a natural abundance level of the nucleides are now commonplace. The scope of chemical applications extends from inorganic, organometallic and organic chemistry to biochemistry and molecular biology, and includes the study of reactive intermediates, biopolymers and enzyme-inhibitor complexes. 

Ion chromatography (1C) is a separation technique related to HPLC. However, because it has so many aspects such as the principle of separation and detection methods, it requires special attention. The mobile phase is usually composed of an aqueous ionic medium and the stationary phase is a solid used to conduct ion exchange. Besides the detection modes based on absorbance and fluorescence, which are identical to those used in HPLC, ion chromatography also uses electrochemical methods based on the presence of ions in a solution. The applications of ion chromatography extend beyond the measurement of cations and anions that initially contributed to the success of the technique. One can measure organic or inorganic species as long as they are polar. 

The extended defect structures that occur in certain non-stoicheiometric compounds have in recent years provided some of the most intriguing problems in solid-state chemistry. The most intensively studied phase showing this class of disorder is Ti02-x> which planar defects known as shear planes have been detected and characterized by electron microscopy. Examples of other simple inorganic compounds containing shear planes are provided by V02 x and The range of... 

---