What is the transformation product of austenite?

What is the transformation product of austenite?

In eutectoid reaction, solid austenite transforms to two solid phases forming a lamellar (eutectic) structure. The lamellas are cementite lamellas and α-ferrite lamellas. The eutectic structure will be coarse when the growth is slow and fine after rapid growth.

What is martensite vs austenite?

Martensitic Stainless Steel Martensite is a body centred cubic form of crystallised iron which is created when heated austenite is rapidly cooled by quenching. Martensitic stainless steels can be heat treated and hardened, but have reduced chemical resistance when compared to austenitic stainless steels.

What is the austenite phase?

Austenite is a high temperature phase and has a Face Centred Cubic (FCC) structure [which is a close packed structure]. The alpha phase is called ferrite. Ferrite is a common constituent in steels and has a Body Centred Cubic (BCC) structure [which is less densely packed than FCC].

Is austenite FCC or BCC?

Between 912 and 1,394 °C, pure iron exists as the gamma phase, austenite, which has the FCC structure. Carbon is more soluble in the FCC phase, which occupies area “γ” on the phase diagram, than it is in the BCC phase.

What happens when martensite is formed?

Martensite is formed in carbon steels by the rapid cooling (quenching) of the austenite form of iron at such a high rate that carbon atoms do not have time to diffuse out of the crystal structure in large enough quantities to form cementite (Fe3C). A very rapid quench is essential to create martensite.

What does austenite transform into when you cool it slowly?

Alpha ferrite forms by the slow cooling of austenite, with the associated rejection of carbon by diffusion. This can begin within a temperature range of 900°C to 723°C, and alpha-ferrite is evident to room temperature.

What is austenite in iron carbon diagram?

Austenite was originally used to describe an iron-carbon alloy, in which the iron was in the face-centred-cubic (gamma-iron) form. It is now a term used for all iron alloys with a basis of gamma-iron. Austenite in iron-carbon alloys is generally only evident above 723°C, and below 1500°C, depending on carbon content.

Why is austenite FCC?

High-temperature austenite, an FCC structure, allows enough space for carbon to squeeze in between the iron atoms. Iron atoms maintain their place on the lattice and carbon atoms become “interstitials.” In the low-temperature ferrite, or BCC structure, however, there is no room for carbon atoms.

Why is the martensitic transformation in steels A diffusion less process?

Introduction to Martensitic Transformation in Steels: A cooling rate faster than its critical cooling rate avoids the transformation of austenite by diffusion processes (to pearlite and/or bainite), but instead transforms to martensite—a diffusion less shear transformation product.

How is the transformation of martensite to austenite completed?

Martensite and austenite coexist as the strain energy released by the former balances the chemical driving force to convert the latter. As the temperature drops, increasing amounts of martensite form until at the Mf (martensite finish) temperature, the transformation of austenite is complete.

Which is the parent phase of austenite crystal?

The crystal structure found at high temperatures is the parent phase, often referred to austenite, and the phase that results from a martensitic transformation is called martensite. The shape memory effect is a direct consequence of a reversible transformation between austenite and martensite.

Which is the parent phase of a martensitic transformation?

A martensitic transformation is a specific type of crystal structure change that occurs when cooling certain specific metals, including Nitinol. The crystal structure found at high temperatures is the parent phase, often referred to austenite, and the phase that results from a martensitic transformation is called martensite.

How long does it take to temper a martensite transformation?

Tempering temperatures of less than 500°C are typically employed for times on the order of minutes to a few hours depending on the steel and part size. The martensite transformation has a number of other features relevant to its role in hardening steel.