Microstructure Evolution in ODS Alloys with a High-Volume Fraction of Nano Oxides

Abstract: Existing oxide dispersion strengthened (ODS) alloys are, besides Ni-based superalloy single crystals, the most creep-resistant materials. The creep resistance of the ODS alloys may, moreover, be significantly improved thanks to increasing the volume fraction of the nano oxides by more than one order of magnitude so that the oxides play a decisive role in strengthening. The present experimental study deals with two systems of such a high-volume fraction of nano oxides, namely, the Fe-11Al-1O and Fe-17Cr-7Al-4Y … Show more

“…Excellent creep strength of the ODS alloys is associated with an attractive interaction between dislocations and nano-oxides as it is successfully modelled by Rösler and Arzt [19], who also predict a threshold stress for creep and its significant drop with coarsening of the nano-oxides. The coarsening kinetics of particles in multicomponent systems is modelled by Fisher et al [20] and experimentally studied e.g., by Bartkova et al [21] or by Svoboda et al [22] indicating a very high 2 of 13 resistance of Y-nano-oxides against coarsening in ODS alloys. The benefits of high creep resistance of ODS alloys at very high temperatures are conditioned by a sufficiently good oxidation resistance.…”

“…The research effort of the authors resulted in development of a mechanically alloyed powder with a very high content of O, allowing production of an ODS alloy (called new-generation ODS alloy by the authors) of rather high nano-oxide volume fraction of about 5%, which exceeds the volume fraction in classical ODS alloys by one order of magnitude [4,6]. The processing of the new-generation ODS alloy consists of three steps [22]: (1) MA to produce chemically homogeneous powders, (2) hot consolidation of the powders by intensive plastic deformation, e.g., by rolling, providing a compact ultra-fine grained alloy due to an intensive dynamic recrystallization and (3) heat treatment to provoke secondary recrystallization leading to rather coarse-grained microstructure conditioning an excellent creep resistance. A complex optimization of the chemical composition of the new-generation ODS alloy performed recently by the authors of the Institute of Physics of Materials leads to conclusion that pure Y-nano-oxides as strengthening particles are much better with respect to coarsening than other nano-oxides [21,22], as well as in terms of the cohesive strength of grain boundaries being influenced by wetting of the nano-oxides (unpublished results).…”

“…The processing of the new-generation ODS alloy consists of three steps [22]: (1) MA to produce chemically homogeneous powders, (2) hot consolidation of the powders by intensive plastic deformation, e.g., by rolling, providing a compact ultra-fine grained alloy due to an intensive dynamic recrystallization and (3) heat treatment to provoke secondary recrystallization leading to rather coarse-grained microstructure conditioning an excellent creep resistance. A complex optimization of the chemical composition of the new-generation ODS alloy performed recently by the authors of the Institute of Physics of Materials leads to conclusion that pure Y-nano-oxides as strengthening particles are much better with respect to coarsening than other nano-oxides [21,22], as well as in terms of the cohesive strength of grain boundaries being influenced by wetting of the nano-oxides (unpublished results). Moreover, the influence of Mo, Ta, La, Ti, Co and Ni alloying on the creep resistance is evaluated as negative or neutral and Cr alloying as slightly positive (unpublished results).…”

The Influence of Aluminum Content on Oxidation Resistance of New-Generation ODS Alloy at 1200 °C

“…Excellent creep strength of the ODS alloys is associated with an attractive interaction between dislocations and nano-oxides as it is successfully modelled by Rösler and Arzt [19], who also predict a threshold stress for creep and its significant drop with coarsening of the nano-oxides. The coarsening kinetics of particles in multicomponent systems is modelled by Fisher et al [20] and experimentally studied e.g., by Bartkova et al [21] or by Svoboda et al [22] indicating a very high 2 of 13 resistance of Y-nano-oxides against coarsening in ODS alloys. The benefits of high creep resistance of ODS alloys at very high temperatures are conditioned by a sufficiently good oxidation resistance.…”

“…The research effort of the authors resulted in development of a mechanically alloyed powder with a very high content of O, allowing production of an ODS alloy (called new-generation ODS alloy by the authors) of rather high nano-oxide volume fraction of about 5%, which exceeds the volume fraction in classical ODS alloys by one order of magnitude [4,6]. The processing of the new-generation ODS alloy consists of three steps [22]: (1) MA to produce chemically homogeneous powders, (2) hot consolidation of the powders by intensive plastic deformation, e.g., by rolling, providing a compact ultra-fine grained alloy due to an intensive dynamic recrystallization and (3) heat treatment to provoke secondary recrystallization leading to rather coarse-grained microstructure conditioning an excellent creep resistance. A complex optimization of the chemical composition of the new-generation ODS alloy performed recently by the authors of the Institute of Physics of Materials leads to conclusion that pure Y-nano-oxides as strengthening particles are much better with respect to coarsening than other nano-oxides [21,22], as well as in terms of the cohesive strength of grain boundaries being influenced by wetting of the nano-oxides (unpublished results).…”

“…The processing of the new-generation ODS alloy consists of three steps [22]: (1) MA to produce chemically homogeneous powders, (2) hot consolidation of the powders by intensive plastic deformation, e.g., by rolling, providing a compact ultra-fine grained alloy due to an intensive dynamic recrystallization and (3) heat treatment to provoke secondary recrystallization leading to rather coarse-grained microstructure conditioning an excellent creep resistance. A complex optimization of the chemical composition of the new-generation ODS alloy performed recently by the authors of the Institute of Physics of Materials leads to conclusion that pure Y-nano-oxides as strengthening particles are much better with respect to coarsening than other nano-oxides [21,22], as well as in terms of the cohesive strength of grain boundaries being influenced by wetting of the nano-oxides (unpublished results). Moreover, the influence of Mo, Ta, La, Ti, Co and Ni alloying on the creep resistance is evaluated as negative or neutral and Cr alloying as slightly positive (unpublished results).…”

The Influence of Aluminum Content on Oxidation Resistance of New-Generation ODS Alloy at 1200 °C

“…However, it was confirmed that they grow during annealing at 1200 • C. As the nano-oxides are very stable against coarsening up to temperatures of 1000 • C, and their number density is kept very high, the Zener pinning effect is also active at these temperatures. The Zener pinning effect decreases due to the coarsening of nano-oxides at temperatures over 1200 • C, and secondary recrystallization takes place [25].…”

“…As the nano-oxides are very stable against coarsening up to temperatures of 1000 °C, and their number density is kept very high, the Zener pinning effect is also active at these temperatures. The Zener pinning effect decreases due to the coarsening of nano-oxides at temperatures over 1200 °C, and secondary recrystallization takes place [25]. It is very difficult to measure the grain size with automatic software and therefore the evaluation is done by in-house software according to the American Society for Testing and Materials (ASTM) E112-13, "Standard Test Methods for Determining Average Grain Size".…”

High Temperature and Corrosion Properties of A Newly Developed Fe-Al-O Based OPH Alloy

Modelling of Processing Steps of New Generation ODS Alloys