Nonmetallic trace elements induced rhenium co-segregation in nickel Σ5 [001](210) symmetrical tilt grain boundary

“…It has a hexagonal network (A3), which it retains up to the melting point-3453 K (3180 • C) (only tungsten and carbon have higher melting points), and thanks to which it is not subject to ductile-brittle transformation [3][4][5]. Rhenium, thanks to its resistance to high temperatures and a very good strength, is used in the production of superalloys, mainly nickel-based ones, from which turbine blades for aircraft engines and gas turbines are made [5][6][7]. The addition of 1-7% of Re to the nickel-based alloy not only contributes to improving its high temperature strength, but also prevents fatigue cracking [1, 3,8].…”

A New Method of Obtaining High Purity Nickel(II) Perrhenate from Waste

“…It has a hexagonal network (A3), which it retains up to the melting point-3453 K (3180 • C) (only tungsten and carbon have higher melting points), and thanks to which it is not subject to ductile-brittle transformation [3][4][5]. Rhenium, thanks to its resistance to high temperatures and a very good strength, is used in the production of superalloys, mainly nickel-based ones, from which turbine blades for aircraft engines and gas turbines are made [5][6][7]. The addition of 1-7% of Re to the nickel-based alloy not only contributes to improving its high temperature strength, but also prevents fatigue cracking [1, 3,8].…”

A New Method of Obtaining High Purity Nickel(II) Perrhenate from Waste

Effect of alloying element segregation on theoretical strength and structural low-energy transition of Ni grain boundaries: A first-principles computational tensile test study

Effect of transition metal segregation on strength of Cu Σ5 [001](210) symmetrical tilt grain boundary: Insight from DFT calculation