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Ion-Selective Electrode Materials

Through systematic investigations of the glass electrode [16—20] it was learned that, above all, the surface structure of the electrode material directly at the solution boundary influences the selectivity. In the interest of the greatest possible selectivity, only the ion to be sensed should have the ability to be reversibly absorbed and released by the electrode material. Investigations by Eisenman et al. [21] showed that the selectivity of glass electrodes is determined by the equilibrium constant of the reaction  [Pg.21]

One can thus explain the proton-selective behavior of the electrode material, or more precisely of the glass gel layer, in that the proton has only a relatively small [Pg.21]

A potassium-barium aluminum silicate glass showed an ion-sensitive behavior for the following series  [Pg.22]

A susceptibility for divalent ions could be shown with electrodes made with the help of natural glasses (for example, obsidan, tuff, tektite) [27]. Unfortunately they are not all specific, giving a mixed potential determined by all mono- and divalent ions present in the test solution. [Pg.22]

The main requirement of a selective electrode material necessary to achieve the maximum exchange current density of one ion in comparison to the others is met if the exchange equilibrium (R4) lies on the side of the indicated ion on the electrode phase. With glass this requirement amounts to a compromise. The stronger an ion is bound in the glass matrix, the more the exchange equilibrium (R4) lies on the side of this ion in the electrode phase, and the less mobile it is in the gel layer. The more mobile an ion is in the gel layer, the less favorable its equilibrium lies. [Pg.26]


The second aspect of biocompatibility is a leaching problem. Ion-selective electrode materials, especially components of solvent polymeric membranes, are subject to leaching upon prolonged contact with physiological media. Membrane components such as plasticizers, ion exchangers and ionophores may activate the clotting cascade or stimulate an immune response. Moreover, they can be potentially toxic when released to the blood stream in significant concentrations. [Pg.127]

A number of divergent applications are described here modification of polymer surfaces (coatings, fibers, films and plastics) modifications leading to superior coating materials isolation, concentration and containment of uranium natural materials for insulation synthesis of sugar substitutes synthesis of anti-arrhythmic drugs fibers which can be spun from chlorinated solvents yet dry cleaned and synthesis of calcium ion selective electrode materials. [Pg.425]

J. Lenik, Preparation and study of an naproxen ion-selective electrode. Materials Science and Technology C, 33 (1), 311-316, 2013. [Pg.226]

An ion-selective electrode based on a sparingly soluble inorganic crystalline material. [Pg.479]

National Institute of Standards and Technology (NIST). The NIST is the source of many of the standards used in chemical and physical analyses in the United States and throughout the world. The standards prepared and distributed by the NIST are used to caUbrate measurement systems and to provide a central basis for uniformity and accuracy of measurement. At present, over 1200 Standard Reference Materials (SRMs) are available and are described by the NIST (15). Included are many steels, nonferrous alloys, high purity metals, primary standards for use in volumetric analysis, microchemical standards, clinical laboratory standards, biological material certified for trace elements, environmental standards, trace element standards, ion-activity standards (for pH and ion-selective electrodes), freezing and melting point standards, colorimetry standards, optical standards, radioactivity standards, particle-size standards, and density standards. Certificates are issued with the standard reference materials showing values for the parameters that have been determined. [Pg.447]

NEW COMPLEX CHALCOGENIDES AS SENSITIVE MATERIALS FOR ION SELECTIVE ELECTRODES... [Pg.319]

De Marco R, Mackey DJ, Zirino A (1997) Response of the jalpaite membrane copper(lI) ion-selective electrode in marine waters. Electroanalysis 9 330-334 Kozicki MN, Mitkova M (2006) Mass transport in chalcogenide electrolyte films - materials and applications. J Non-Cryst Solids 352 567-577... [Pg.347]

Ion probes. Determining the level of ions in solution also helps to control corrosion. An increase in concentration of specific ions can contribute to scale formation, which can lead to a corrosion-related failure. Ion-selective electrode measurements can be included, just as pH measurements can, along with other more typical corrosion measurements. Especially in a complete monitoring system, this can add information about the effect of these ions on the material of interest at the process plant conditions. [Pg.26]

There are also RMs which are prepared for a specific application and are used for validation of relevant methods. Cobbaert et al. (1999) made use of Ion Selective Electrode (ISE)-protein-based materials when evaluating a procedure which used an electrode with an enzyme-linked biosensor to determine glucose and lactate in blood. Chance et al. (1999) are involved with the diagnosis of inherited disorders in newborn children and they prepared a series of reference materials consisting of blood spotted onto filter paper and dried, from which amino-acids can be eluted and... [Pg.113]

Selectivity coefficients values for K - and Na -ISFETs with the optimized ion-sen-sing membranes encapsulating valinomycin and bis(12-crown-4) are summarized in Fig. 9. The selectivity coefficient for with respect to Na in the K -ISFET is 2 x 10 " and that for Na with respect to in the Na -ISFET is 3 x 10. The selectivity coefficient values are similar to those for the ISFETs and ion-selective electrodes with the previous membrane materials containing the same neutral carriers. The high sensitivity and selectivity for the neutral-carrier-type ISFETs based on sol-gel-derived membranes can last for at least 3 weeks. [Pg.594]

Principles and Characteristics Combustion analysis is used primarily to determine C, H, N, O, S, P, and halogens in a variety of organic and inorganic materials (gas, liquid or solid) at trace to per cent level, e.g. for the determination of organic-bound halogens in epoxy moulding resins, halogenated hydrocarbons, brominated resins, phosphorous in flame-retardant materials, etc. Sample quantities are dependent upon the concentration level of the analyte. A precise assay can usually be obtained with a few mg of material. Combustions are performed under controlled conditions, usually in the presence of catalysts. Oxidative combustions are most common. The element of interest is converted into a reaction product, which is then determined by techniques such as GC, IC, ion-selective electrode, titrime-try, or colorimetric measurement. Various combustion techniques are commonly used. [Pg.595]

Principles and Characteristics A substantial percentage of chemical analyses are based on electrochemistry, although this is less evident for polymer/additive analysis. In its application to analytical chemistry, electrochemistry involves the measurement of some electrical property in relation to the concentration of a particular chemical species. The electrical properties that are most commonly measured are potential or voltage, current, resistance or conductance charge or capacity, or combinations of these. Often, a material conversion is involved and therefore so are separation processes, which take place when electrons participate on the surface of electrodes, such as in polarography. Electrochemical analysis also comprises currentless methods, such as potentiometry, including the use of ion-selective electrodes. [Pg.666]

The material is presented in 17 chapters, covering topics such as trends in ion selective electrodes, advances in electrochemical immunosensors, modem glucose biosensors for diabetes management, biosensors based on nanomaterials (e.g. nanotubes or nanocrystals), biosensors for nitric oxide and superoxide, or biosensors for pesticides. [Pg.22]

In contrast to other analytical methods, ion-selective electrodes respond to an ion activity, not concentration, which makes them especially attractive for clinical applications as health disorders are usually correlated to ion activity. While most ISEs are used in vitro, the possibility to perform measurements in vivo and continuously with implanted sensors could arm a physician with a valuable diagnostic tool. In-vivo detection is still a challenge, as sensors must meet two strict requirements first, minimally perturb the in-vivo environment, which could be problematic due to injuries and inflammation often created by an implanted sensor and also due to leaching of sensing materials second, the sensor must not be susceptible to this environment, and effects of protein adsorption, cell adhesion, and extraction of lipophilic species on a sensor response must be diminished [13], Nevertheless, direct electrolyte measurements in situ in rabbit muscles and in a porcine beating heart were successfully performed with microfabricated sensor arrays [18],... [Pg.96]


See other pages where Ion-Selective Electrode Materials is mentioned: [Pg.322]    [Pg.5585]    [Pg.291]    [Pg.221]    [Pg.21]    [Pg.21]    [Pg.23]    [Pg.25]    [Pg.27]    [Pg.322]    [Pg.5585]    [Pg.291]    [Pg.221]    [Pg.21]    [Pg.21]    [Pg.23]    [Pg.25]    [Pg.27]    [Pg.465]    [Pg.141]    [Pg.1025]    [Pg.220]    [Pg.225]    [Pg.563]    [Pg.579]    [Pg.141]    [Pg.159]    [Pg.188]    [Pg.196]    [Pg.218]    [Pg.75]    [Pg.126]    [Pg.337]    [Pg.59]    [Pg.586]    [Pg.587]    [Pg.587]    [Pg.596]    [Pg.810]    [Pg.669]    [Pg.36]    [Pg.308]   


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