Abstract
In the present text we discuss on electronic properties arising from polycrystalline semiconductor ceramics of SnO2, TiO2 and (Sn xTi1-x)O2 solid solution rutile-type structure. This is intended to be a short overview of the most recent papers in this area. One of the most important content discussed in this text is based on sinterability of these polycrystalline ceramics, which depends on the target application used to project porous or highly dense microstructure. The majority of discussion is focused in two main applications: varistor and sensor. In both applications there are similarities involved in the control of the sensor and varistor properties, which can mainly ascribed to the grain boundary structure and composition. The similarities found are consistently explained by the fact that all of these n-type semicondutor ceramics have the tendency to establish a grain boundary region with a "p-type semiconductor nature" (due to metal transition atoms segregated at the grain boundary region and then favors negative charged species to adsorb and enrich this region). This configuration enables electrons to become localized on the surfaces, giving rise to a negative surface and, as a result, electron depletion layers are formed, acting as potential barriers which control the properties of the mentioned devices.
Highlights
IntroductionTiO crystalline semiconductor that it would be impossible to discuss 2 all of them here
There are so many exciting ideas and new data and so many important technologies and devices developing based on SnO and 2TiO crystalline semiconductor that it would be impossible to discuss 2 all of them here
It is important to emphasize that dense ZrO is mainly applied as a bulk-type sensor material for pollutant gases such as NOx or O2, contrary to the SnO2 or TiO2 that are mainly used as thin-type sensor material
Summary
TiO crystalline semiconductor that it would be impossible to discuss 2 all of them here. SnO2 and TiO2 are ceramic materials that depend on its processing, microstructure and doping agents. These crystalline ceramic materials can be applied as component for communication, computation and control devices. They are used as insulator, as capacitor dielectrics, as conductors, which may be metallic, semiconductor, ionic, ohmic, or nonlinear. The importance of interfaces to semiconductor technology is well known for electronic and ionic ceramics since they control the microstructure development. SnO and TiO as semiconductor oxides are used in a broad range of applications in which the defect chemistry of interfaces provides important chemical or electrical functionalities. The control of the microstructure with specific dopants and processing in the pure oxides can be used to design different kinds of devices and applications as shall be discussed here
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