Abstract
Low-temperature treatments have become a valuable method for improving the surface hardness of stainless steels, and thus their tribological properties, without impairing their corrosion resistance. By using treatment temperatures lower than those usually employed for nitriding or carburizing of low alloy steels or tool steels, it is possible to obtain a fairly fast (interstitial) diffusion of nitrogen and/or carbon atoms; on the contrary, the diffusion of substitutional atoms, as chromium atoms, has significantly slowed down, therefore the formation of chromium compounds is hindered, and corrosion resistance can be maintained. As a consequence, nitrogen and carbon atoms can be retained in solid solutions in an iron lattice well beyond their maximum solubility, and supersaturated solid solutions are produced. Depending on the iron lattice structure present in the stainless steel, the so-called “expanded austenite” or “S-phase”, “expanded ferrite”, and “expanded martensite” have been reported to be formed. This review summarizes the main studies on the characteristics and properties of these “expanded” phases and of the modified surface layers in which these phases form by using low-temperature treatments. A particular focus is on expanded martensite and expanded ferrite. Expanded austenite–S-phase is also discussed, with particular reference to the most recent studies.
Highlights
Stainless steels are used for a wide variety of applications, from components for the chemical and power engineering industries to household utensils and kitchenware [1,2].Their success is due to their resistance to general corrosion in many environments, owing to the thin, adherent, and self-healing chromium-rich oxide film, which forms on the steel surface in the presence of oxygen
This review summarizes the main studies on the characteristics and properties of these “expanded” phases and of the modified surface layers in which these phases form by using low-temperature treatments
The aim of the present review is to report the main studies on the formation, characteristics, and properties of the “expanded” phases obtained in stainless steels by using low-temperature treatments, and on the characteristics of the modified layers in which they form, with a particular focus on expanded martensite and expanded ferrite
Summary
Stainless steels are used for a wide variety of applications, from components for the chemical and power engineering industries to household utensils and kitchenware [1,2]. When the treatment temperature of nitriding or carburizing process is decreased, so that significant Cr (substitutional) diffusion is avoided while interstitial atoms can diffuse, in the so-called para-equilibrium conditions [13], it is possible to inhibit the formation of Cr. Metals 2022, 12, 331 nitrides and carbides precipitates and obtain supersaturated solid solutions of the diffused interstitial atoms in austenite, ferrite, or martensite, which allow for a surface hardness increase without impairing the corrosion resistance. The aim of the present review is to report the main studies on the formation, characteristics, and properties of the “expanded” phases obtained in stainless steels by using low-temperature treatments, and on the characteristics of the modified layers in which they form, with a particular focus on expanded martensite and expanded ferrite. In the fourth section, expanded austenite–S-phase, formed in austenitic stainless steels, is discussed, with particular reference to the most recent studies
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