Low energy–high flux nitrogen implantation of an oxide-dispersion-strengthened FeAl intermetallic alloy

“…The k p values (Fig 3b) from the first part of the oxidation curve is near of the measured values when pure iron is oxidised at 400°C [15]; then this observation could be consistent with the presence of α-Fe detected after the implantation process [16,17]. Conversely, the second parabolic constant is much lower and compares well to the one of the untreated FeAl.…”

Oxidation mechanisms of low energy-high flux nitrided ODS FeAl intermetallic alloy

“…The k p values (Fig 3b) from the first part of the oxidation curve is near of the measured values when pure iron is oxidised at 400°C [15]; then this observation could be consistent with the presence of α-Fe detected after the implantation process [16,17]. Conversely, the second parabolic constant is much lower and compares well to the one of the untreated FeAl.…”

Oxidation mechanisms of low energy-high flux nitrided ODS FeAl intermetallic alloy

“…Ion implantation improves the physical and mechanical properties of the material surface (hardness, heat resistance, wear resistance, fatigue strength, corrosion resistance, etc.) [20,[26][27][28][29][30]. The main advantages of ion implantation include the absence of adhesion problems [31] (since ions are implanted into the material at an energy of about 106 eV) and no influence on the geometric dimensions of workpieces, which is relevant for cutting tools or threaded joints [32].…”

Investigation of Corrosion Properties and Composition of the Surface Formed on AISI 321 Stainless Steel by Ion Implantation

Change in the Structure and Corrosion Resistance of a Nickel-Chrome Coating on Stainless Steel During Implantation of High Energy Al+ and B+ Ions