Semiconductors conductive polymers

In the context of this chapter, we focus on the undoped or lightly doped 7i-conjugated systems that are commonly referred to as organic semiconductors. Conducting polymers, such as PEDOT PSS, plexcore, polyaniline, polypyrrole, and others are not addressed here as their charge transfer mechanisms are rather different and would warrant an article in its own right. 

Among the different types of sensors, the most commercially used ones in e-nose systems include metal oxide semiconductors, conducting polymers, bulk acoustic waves, surface acoustic waves, quartz-microbalance sensors and tin oxide sensors. 

The current chapter deals with FT in solid-state devices, which lack a solution but may involve electron transport, activated redox reactions, and/or ion motion. Extensive past investigations of transport in organic semiconductors, conducting polymers, and redox polymers provide important... 

J. Kanicki, Polymeric Semiconductor Contacts and Photovoltaic Applications in Handbook of Conducting Polymers (Ed. T. Skolheim), Dekker, New York 1986. 

The interest of physicists in the conducting polymers, their properties and applications, has been focused on dry materials 93-94 Most of the discussions center on the conductivity of the polymers and the nature of the carriers. The current knowledge is not clear because the conducting polymers exhibit a number of metallic properties, i.e., temperature-independent behavior of a linear relation between thermopower and temperature, and a free carrier absorption typical of a metal. Nevertheless, the conductivity of these specimens is quite low (about 1 S cm"1), and increases when the temperature rises, as in semiconductors. However, polymers are not semiconductors because in inorganic semiconductors, the dopant substitutes for the host atomic sites. In conducting polymers, the dopants are not substitutional, they are part of a nonstoichiometric compound, the composition of which changes from zero up to 40-50% in... 

Chemical and electrochemical techniques have been applied for the dimensionally controlled fabrication of a wide variety of materials, such as metals, semiconductors, and conductive polymers, within glass, oxide, and polymer matrices (e.g., [135-137]). Topologically complex structures like zeolites have been used also as 3D matrices [138, 139]. Quantum dots/wires of metals and semiconductors can be grown electrochemically in matrices bound on an electrode surface or being modified electrodes themselves. In these processes, the chemical stability of the template in the working environment, its electronic properties, the uniformity and minimal diameter of the pores, and the pore density are critical factors. Typical templates used in electrochemical synthesis are as follows ... 

Intrinsically conducting polymers, 13 540 Intrinsic bioremediation, 3 767 defined, 3 759t Intrinsic detectors, 22 180 Intrinsic fiber-optic sensors, 11 148 Intrinsic magnetic properties, of M-type ferrites, 11 67-68 Intrinsic photoconductors, 19 138 Intrinsic rate expressions, 21 341 Intrinsic semiconductors, 22 235-236 energy gap at room temperature, 5 596t Intrinsic strength, of vitreous silica, 22 428 Intrinsic-type detectors, cooling, 19 136 Intrinsic viscosity (TV), of thermoplastics, 10 178... 

One of the most important applications of nanoporous membranes is as nanoscaffolds in template synthesis, to replicate the structural features of the nanopores, or patterns, into metals [233], carbons [234], semiconductors [235,236], conductive polymers [237,238], and other materials [239]. The important characteristics of template synthesis have been best reviewed by Martin [188,240]. In short, it is a robust, general method suitable for the... 

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