TY - JOUR
T1 - Fabrication and thermal stability of a nanocrystalline Ni-Al-Cr alloy
T2 - Comparison with pure Cu and Ni
AU - Oh-ishi, Keiichiro
AU - Horita, Zenji
AU - Smith, David J.
AU - Valiev, Ruslan Z.
AU - Nemoto, Minoru
AU - Langdon, Terence G.
N1 - Funding Information:
This work was supported by the Light Metal Educational Foundation of Japan; a Grant-in-Aid for Scientific Research from the Ministry of Education, Science, Sports and Culture of Japan; the Japan Society for the Promotion of Science; the United States Army Research Office under Grant No. 68171-98-M-5682; and the National Science Foundation of the United States under Grant Nos. DMR-9625969 and INT-9602919. High-resolution electron micrographs were recorded at the Center for High Resolution Electron Microscopy at Arizona State University.
PY - 1999/11
Y1 - 1999/11
N2 - A Ni-Al-Cr alloy with an initial grain size of approximately 60 μm was subjected to torsion straining to a strain of approximately 7 at room temperature, thereby reducing the grain size to approximately 34 nm. Similar torsion straining with samples of pure Cu and pure Ni gave grain sizes of approximately 170 and approximately 130 nm, respectively. Inspection of the Ni-Al-Cr alloy after torsion straining revealed highly strained regions containing dislocations associated with lattice distortions but with an absence of any Ni3Al ordered phase. The ultrafine grains in the Ni-Al-Cr alloy were extremely stable at high temperatures, and it was possible to retain a grain size of less than 100 nm after annealing at temperatures up to approximately 900 K. By contrast, there was rapid grain growth in the samples of pure Cu and Ni at annealing temperatures in the vicinity of approximately 500 K. The stability of the grains in the Ni-Al-Cr alloy is attributed to the formation of a Ni3Al-based ordered phase after annealing at approximately 650-700 K. The presence of this phase also leads to an apparent negative slope in the standard Hall-Petch relationship.
AB - A Ni-Al-Cr alloy with an initial grain size of approximately 60 μm was subjected to torsion straining to a strain of approximately 7 at room temperature, thereby reducing the grain size to approximately 34 nm. Similar torsion straining with samples of pure Cu and pure Ni gave grain sizes of approximately 170 and approximately 130 nm, respectively. Inspection of the Ni-Al-Cr alloy after torsion straining revealed highly strained regions containing dislocations associated with lattice distortions but with an absence of any Ni3Al ordered phase. The ultrafine grains in the Ni-Al-Cr alloy were extremely stable at high temperatures, and it was possible to retain a grain size of less than 100 nm after annealing at temperatures up to approximately 900 K. By contrast, there was rapid grain growth in the samples of pure Cu and Ni at annealing temperatures in the vicinity of approximately 500 K. The stability of the grains in the Ni-Al-Cr alloy is attributed to the formation of a Ni3Al-based ordered phase after annealing at approximately 650-700 K. The presence of this phase also leads to an apparent negative slope in the standard Hall-Petch relationship.
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U2 - 10.1557/JMR.1999.0569
DO - 10.1557/JMR.1999.0569
M3 - Article
AN - SCOPUS:0033221847
SN - 0884-2914
VL - 14
SP - 4200
EP - 4207
JO - Journal of Materials Research
JF - Journal of Materials Research
IS - 11
ER -