Microstructure Change of B2 Precipitates in an Fe-Al-Ni Alloy due to Two-Step Heat-Treatment

Junji Yamanaka; Chiaya Yamamoto; Yasuhiro Kuno; Minoru Doi

doi:10.4028/www.scientific.net/MSF.706-709.2496

Paper Titles

Influence of Stacking Fault Energy on Creep Mechanism of a Single Crystal Nickel-Based Superalloy Containing Re
p.2474

Solidification Structure of Incoloy800 Superalloy with Electromagnetic Field
p.2480

Modern Control Theory Applied to Remelting of Superalloys
p.2484

Surface Recrystallization and Twin Formation in a Single Crystal Superalloy
p.2490

Microstructure Change of B2 Precipitates in an Fe-Al-Ni Alloy due to Two-Step Heat-Treatment
p.2496

Recrystallization in HR3C Austenitic Heat Resistant Steel
p.2502

Foresight of Material Surface Engineering as a Tool Building a Knowledge-Based Economy
p.2511

Study on Surface Roughness Transformation during Metal Rolling
p.2517

Antifouling Stainless Steel Surface: Competition between Roughness and Surface Energy
p.2523

HomeMaterials Science ForumMaterials Science Forum Vols. 706-709Microstructure Change of B2 Precipitates in an...

Microstructure Change of B2 Precipitates in an Fe-Al-Ni Alloy due to Two-Step Heat-Treatment

Abstract:

We have been studying the microstructure change of B2 cubic precipitates into an A2+B2 complex structure in Fe-Al-Ni alloy. In this study, we carried out detailed observation using focused ion beam (FIB) and scanning transmission electron microscopy (STEM). First, Fe-14.3at%Al-10.3at%Ni solid solution was prepared. Secondly, the specimens were heated at 1173 K, at which they formed B2 cubic precipitates (ordered bcc) dispersed in an A2 matrix (disordered bcc). After that, the B2/A2 two-phase specimen was annealed at 973 K. Then we fabricated STEM specimens using FIB, followed by high-resolution secondary electron imaging. We repeated this slice-and-observation procedure to determine the detailed microstructure of this heat-treated alloy. At the early stage of the 973 K annealing, the A2 phase appeared in the original B2 precipitates and showed a spongelike structure, whereas small nanometer-order B2 particles appeared in the A2 matrix. The A2/B2 interface at this stage showed no anisotropic morphology. Therefore, the main driving force of this process may not be strain energy, but chemical and interface energies. Further annealing at 973 K decreased the number of small B2 particles in the A2 matrix, and these particles dissolved into the matrix eventually. The annealing also changed the A2/B2 spongelike structure, which was observed in the original B2 precipitates, into simple structures such as the A2 core and B2 crust. Then the B2 phase showed ordinal coarsening behavior. When B2 precipitates, which had hollow cubic morphology, were observed to be very close to each other, the face-centered area of the B2 crust tended to dissolve and only large B2 precipitates remained.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volumes 706-709)

Pages:

2496-2501

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.706-709.2496

Citation:

Cite this paper

Online since:

January 2012

Authors:

Junji Yamanaka, Chiaya Yamamoto, Yasuhiro Kuno, Minoru Doi

Keywords:

B2 Ordered Phase, Phase Separation, Phase Transformation, Precipitate Morphology, Scanning Transmission Electron Microscopy

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] A.G. Khachaturyan: Theory of Structural Transformations in Solids (John Wiley and Sons, NY, 1983).

Google Scholar

[2] M. Doi: Prog. Mater. Sci. Vol. 40 (1996), p.79.

Google Scholar

[3] W.C. Johnson and J.W. Cahn (with P.W. Voorhees): in The Selected Works of John W. Cahn, edited by W.C. Carter and W.C. Johnson, TMS, Warrendale, PA (1998), p.437.

DOI: 10.1002/9781118788295.ch46

Google Scholar

[4] P. Fratzl, O. Penrose and J.L. Lebowitz: J. Stat. Phys. Vol. 95 (1999), p.1429.

Google Scholar

[5] T. Koyama, M. Doi and S. Naito: Mat. Res. Soc. Symp. Proc. Vol. 646 (2001), N2. 2. 1.

Google Scholar

[6] M. Doi, T. Kozakai, T. Koyama and S. Naito: in Ti-2003, Science and Technology, edited by G. Lütjering and J. Albrecht, Wiley-VCH, Weinheim (2004), p.1075.

Google Scholar

[7] M. Doi, T. Koyama and T. Kozakai: in 4th Pacific Rim Inter. Conf. on Advanced Materials and Processing (PRICM4), edited by S. Hanada et al., Jpn. Inst. Metals, Sendai (2001), p.741.

Google Scholar

[8] M. Doi, T. Moritani, T. Kozakai and M. Wakano: ISIJ Inter. Vol. 46 (2006), p.155.

Google Scholar

[9] M. Doi, H. Kumagai, K. Nakashima and T. Kozakai: Mater. Res. Soc. Symp. Proc. Vol. 980 (2007), 0980-II05-26.

Google Scholar

[10] Y. Kuno, Y. Nakane, T. Kozakai, M. Doi, J. Yamanak, C. Yamamoto and S. Naito: Mater. Sci. Forum Vol. 638-642 (2010), p.2274.

DOI: 10.4028/www.scientific.net/msf.638-642.2274

Google Scholar

[11] M. Doi: Mater. Sci. Forum Vol. 638-642 (2010), p.2215.

Google Scholar