This handy reference compiles the latest data on the corrosion behavior of materials coming into contact with CO2 -- with 95% of the contents previously unpublished.
It is clearly structured according to material, and covers metals, non-metallic inorganic materials and plastics as well as including information about corrosion protection.
The result is a must-have for all engineers and scientists dealing with corrosion problems in CO2-containing environments.

Corrosion resistance is the property of a material to resist corrosion attack in a particular aggressive environment. Although titanium, tantalum and zirconium are not noble metals, they are the best choice whenever high corrosion resistance is required. The exceptionally good corrosion resistance of these high-performance metals and their alloys results from the formation of a very stable, dense, highly adherent, and self-healing protective oxide film on the metal surface. This naturally occurring oxide layer prevents chemical attack of the underlying metal surface. This behavior also means, however, that high corrosion resistance can be expected only under neutral or oxidizing conditions. Under reducing conditions, a lower resistance must be reckoned with. Only very few inorganic and organic substances are able to attack titanium, tantalum or zirconium at ambient temperature. As the extraordinary corrosion resistance is coupled with an excellent formability and weldability these materials are very valuable for a large number of applications, such as heat exchangers, reaction vessels, funace construction, radiation shielding, implants for medical technology, and capacitor components in electronics.

Derived from the renowned" DECHEMA Corrosion Handbook," this text provides a comprehensive overview of corrosion protection and prevention on the high-performance materials Titanium, Tantalum and Zirconium.

This must-have reference for all chemical engineers, material scientists and chemists working with steel or acidic media explains how to strengthen the corrosion resistance of steels as reaction, transport and storage devices against lyes (hydroxides) and organic acids. The handbook contains comprehensive information, including tabulated data and references, on the corrosion properties of the following materials: Unalloyed steels and cast steel Unalloyed cast iron High-alloy cast iron High-silicon cast iron Structural steels with up to 12% chromium Ferritic chromium steels with more than 12% chromium Ferritic-austenitic steels with more than 12% chromium High-alloy multiphase steels Ferritic/perlitic-martensitic steels Ferritic-austenitic steels/duplex steels Austenitic chromium-nickel steels Austenitic chromium-nickel-molybdenum steels Austenitic chromium-nickel steels with special alloying additions Special iron-based alloys The following corrosive media are considered: Acetic Acid Alkanecarboxylic Acids Carbonic Acid Formic Acid Sulfonic Acids Alkaline Earth Hydroxides Ammonia and Ammonium Hydroxide Lithium Hydroxide Potassium Hydroxide Sodium Hydroxide

This handbook is derived from the online reference "Corrosion Handbook", bringing together the relevant information about corrosion protection and prevention for steels, one of the most widely used materials. It provides comprehensive information, including tabulated data and references, on the corrosion properties of the following materials: Unalloyed steels and cast steel, unalloyed cast iron, high-alloy cast iron, high-silicon cast iron, structural steels with up to 12% chromium, ferritic chromium steels with more than 12% chromium, ferritic-austenitic steels with more than 12% chromium, high-alloy multiphase steels, ferritic/perlitic-martensitic steels, ferritic-austenitic steels/duplex steels, austenitic chromium-nickel steels, austenitic chromium-nickel-molybdenum steels, austenitic chromium-nickel steels with special alloying additions, special iron-based alloys, and zinc. The following corrosive media are considered: Seawater, brackish water, industrial waste water, municipal waste water, drinking water, high-purity water.

Bringing together the widespread information on the topic, this handbook and ready reference is clearly structured according to the various media that can corrode and damage aluminium and aluminium compounds, while also discussing methods of prevention.
With its coverage of multi-talented compounds and energy-saving materials, this is a must-have for all those working in the relevant industries.

This book is a review of corrosion and thermal protection topics associated with coatings applied in high temperature applications, namely catalytic converters, combustion and steam environments, and gas turbines. Information on corrosion influencing mechanisms and their impact are reviewed.

This volume by Michael SchA1/4tze, a world leader in this area of research, is the first volume to be published in the series. The formation of oxide layers is one of the most important areas of corrosion science and the author brings together for the first time in an English language text, work which has, until now, remained scattered. Contents: Basic Requirements for the Protective Action of Oxide Scales; Development of Oxide Scales in High Temperature Technology; Mechanical Stresses in Oxide Scales and their Causes; Deformation Behaviour and Deformation Mechanisms in Oxides; Damage to the Oxide Scale Resulting from Mechanical Stresses; Healing of Oxide Scale Damage; Depletion by Oxidation and Crack Healing of Alloying Elements forming Protective Scales. This book is invaluable for researchers working on the formation and behaviour of oxide layers, for those working on the storage, transport and use of corrosive materials and for industrial chemists, engineers, defence and materials scientists. The Institute of Corrosion and Wiley Series on Corrosion and Protection provides compelling volumes on the science and engineering technology of corrosion and protection. The volumes cover the whole range of knowledge and experience in the field from basic teaching texts at the undergraduate or practising technologist level to state-of-the-art volumes for postgraduates and experienced corrosion engineers. All volumes in the series are reviewed and endorsed by the Institute of Corrosion ensuring their accuracy and technical excellence are to the highest standard.

Recent initiatives and developments in high temperature technology aim at the exploitation of fuels end processes at the edge of present materials capabilities, driving service temperatures higher and operating within ever more aggressive environmental conditions. The major driving force behind this trend is increased efficiencies and further growing efforts in environmental protection. The key to reliable operation of components for sufficiently long service periods to a large extent lies in the high temperature properties of the materials used, with high temperature corrosion resistance as the major life and performance-limiting factor. As conventional alloy design invariably leads to a compromise between mechanical strength and corrosion resistance industry has turned to coatings to provide improved materials performance. Consequently there is extensive worldwide activity to develop high performance protective coating systems, to prevent or minimise damage by corrosion, as well as by abrasion, wear and erosion at elevated temperature. Many of these systems (which may consist of surface modified bulk materials or genuine coating systems and in some cases also of special alloy approaches) are based on systematic development starting from present theoretical understanding including laboratory data and ending up in tailor-made solutions for industrial applications.