Iron – Nickel-based Superalloy

superalloys - inconel - turbine bladeSuperalloys, or high-performance alloys, are non-ferrous alloys that exhibit outstanding strength and surface stability at high temperatures. Their ability to operate safely at a high fraction of their melting point (up to 85% of their melting points (Tm) expressed in degrees Kelvin, 0.85) is their key characteristics. Superalloys are generally used at temperatures above 540 °C (1000 °F), as at these temperatures ordinary steel and titanium alloys are losing their strengths, also corrosion is common in steels at this temperature. At high temperatures, superalloys retain mechanical strength, resistance to thermal creep deformation, surface stability, and resistance to corrosion or oxidation. Some nickel-based superalloys can withstand temperatures beyond 1200°C, depending on the composition of the alloy.​ Superalloys are often cast as a single crystal, while grain boundaries may provide strength, they decrease creep resistance.

Iron – Nickel-based Superalloys

Fe-based superalloys have showed creep and oxidation resistance similar to that of Ni-based superalloys, while being far less expensive to produce. The most important class of this group are those alloys that are strengthened by an intermetallic compound precipitation in an FCC matrix.


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