title   
  

Effect of high-density nanoparticles on recrystallization and texture evolution in ferritic alloys

Aydoğan, Eda and Rietema, Connor J. and Carvajal-Nunez, Ursula and Vogel, Sven C. and Li, Meimei and Maloy, Stuart A. (2019) Effect of high-density nanoparticles on recrystallization and texture evolution in ferritic alloys. Crystals, 9 (3). ISSN 2073-4352

[img]
Preview
PDF (Listed in DOAJ as an open access journal) - Requires a PDF viewer such as GSview, Xpdf or Adobe Acrobat Reader
4Mb

Official URL: http://dx.doi.org/10.3390/cryst9030172

Abstract

Ferritic alloys are important for nuclear reactor applications due to their microstructural stability, corrosion resistance, and favorable mechanical properties. Nanostructured ferritic alloys having a high density of Y-Ti-O rich nano-oxides (NOs < 5 nm) are found to be extremely stable at high temperatures up to ~1100 C. This study serves to understand the effect of a high density of nano-particles on texture evolution and recrystallization mechanisms in ferritic alloys of 14YWT (14Cr-3W-0.4Ti-0.21Y-Fe wt %) having a high density of nano-particles and dispersion-free FeCrAl (13Cr-5.2Al-0.05Y-2Mo-0.2Si-1Nb wt %). In order to investigate the recrystallization mechanisms in these alloys, neutron diffraction, electron backscattered diffraction, and in situ and ex situ transmission electron microscopy have been utilized. It has been observed that even though the deformation textures of both the 14YWT and FeCrAl alloys evolved similarly, resulting in either the formation (in FeCrAl alloy) or increase (in 14YWT) in gamma-fiber texture, the texture evolution during recrystallization is different. While FeCrAl alloy keeps its gamma-fiber texture after recrystallization, 14YWT samples develop a epsilon-fiber as a result of annealing at 1100 C, which can be attributed to the existence of NOs. In situ transmission electron microscopy annealing experiments on 14YWT show the combination and growth of the lamellar grains rather than nucleation; however, the recrystallization and growth kinetics are slower due to NOs compared to FeCrAl.

Item Type:Article
Uncontrolled Keywords:nano-structured ferritic alloys (NFAs); FeCrAl alloys; nano-oxides (NOs); neutron diffraction; texture; recrystallization
Subjects:Q Science > Q Science (General)
T Technology > TA Engineering (General). Civil engineering (General) > TA630-695 Structural engineering (General)
T Technology > TN Mining engineering. Metallurgy > TN600-799 Metallurgy
ID Code:37214
Deposited By:Eda Aydoğan
Deposited On:23 Aug 2019 12:29
Last Modified:23 Aug 2019 12:29

Repository Staff Only: item control page