It may be argued that silicon, carbon, hydrogen, oxygen, and iron are among the most important elements on our planet, because of their involvement in geological, biol- ical, and technological processes and phenomena. All of these elements have been studied exhaustively, and voluminous material is available on their properties. Included in this material are numerous accounts of their electrochemical properties, ranging from reviews to extensive monographs to encyclopedic discourses. This is certainly true for C, H, O, and Fe, but it is true to a much lesser extent for Si, except for the specific topic of semiconductor electrochemistry. Indeed, given the importance of the elect- chemical processing of silicon and the use of silicon in electrochemical devices (e. g. , sensors and photoelectrochemical cells), the lack of a comprehensive account of the electrochemistry of silicon in aqueous solution at the fundamental level is surprising and somewhat troubling. It is troubling in the sense that the non-photoelectrochemistry of silicon seems “to have fallen through the cracks,” with the result that some of the electrochemical properties of this element are not as well known as might be warranted by its importance in a modern technological society. Dr. Zhang’s book, Electrochemical Properties of Silicon and Its Oxide, will go a long way toward addressing this shortcoming. As with his earlier book on the elect- chemistry of zinc, the present book provides a comprehensive account of the elect- chemistry of silicon in aqueous solution.
Biocorrosion refers to corrosion influenced by bacteria adhering to surfaces in biofilms. Biocorrosion is a major problem in areas such as cooling systems and marine structures where biofilms can develop. This book summarises key recent research in this subject. Part one looks at theories of biocorrosion and measurement techniques. Part two discusses how bacteria and biofilms result in biocorrosion. The final part of the book includes case studies of biocorrosion in areas as diverse as buildings, fuels, marine environments and cooling systems. - Provides a detailed overview of biocorrosion and the different scientific and/or industrial problems related to microbially induced corrosion - Introduces a variety of investigative techniques and methodologies that are employed in diagnosing and evaluating microbially induced corrosion - Includes case studies on: biodeterioration of building materials; biocorrosion issues associated with diesel and biofuels; marine biocorrosion; corrosion of open recirculating cooling water systems and cooling system components; the effect of H2S on steel corrosion
These 22 contributions concentrate primarily on newer applications of the staple EIS technique, and secondarily, on the more recent use of ENA in corrosion research. Papers treat experimental aspects of EIS and data analysis; EIS for investigating the protective properties and degradation of polymer coatings; and EIS in combination with other techniques to study specific corrosion phenomena, e.g., the corrosive rates of steel in soil environments. Mansfeld (U. of Southern California), et al., describe the use of both techniques to monitor the corrosion behavior of active and passive systems exposed to chloride media. The volume includes facts about the Electrochemical Society. Annotation copyrighted by Book News Inc., Portland, OR.