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Journal of Materials Science

Erschienen in:

01.03.2014

Positron annihilation study on deformation-induced Au precipitation in Fe–Au and Fe–Au–B–N alloys

verfasst von: S. Zhang, H. Schut, J. Čížek, F. D. Tichelaar, E. Brück, S. van der Zwaag, N. H. van Dijk

Erschienen in: Journal of Materials Science | Ausgabe 6/2014

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Abstract

We have investigated the potential self-healing of deformation-induced defects by Au precipitation during isothermal aging at 550 °C in Fe–Au and Fe–Au–B–N alloys using positron annihilation spectroscopy. Two different samples with 0 and 24 % pre-strain were used to study the influence of dislocations on the Au precipitation. Dislocations introduced prior to the aging process play an essential role in the formation of Au precipitates. The Coincidence Doppler broadening (CDB) technique shows that Au precipitation in the matrix occurs in the pre-strained samples only. TEM observations confirm the heterogeneous nature of the Au precipitation which occurs exclusively on dislocations and grain boundaries. The evolution of S and W parameters derived from the CDB indicates a three-stage precipitation process for the pre-strained samples. Both the hardness tests and the positron annihilation spectroscopy indicate that the addition of boron and nitrogen to the Fe–Au alloy causes a deceleration of the Au precipitation in the pre-strained samples, but does not alter the defect-induced mechanism of the Au precipitation. The defect-induced Au precipitation provides a promising site-specific autonomous repair mechanism to extend the lifetime of Fe-based alloys for high temperature structural applications.

Vorheriger Artikel Mechanical characterization of hollow ceramic nanolattices

Nächster Artikel Fluoro-modified elastomeric polyurethanes: effects of synthesis procedure on properties and morphology

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Laha K, Kyono J, Kishimoto S, Shinya N (2005) Beneficial effect of B segregation on creep cavitation in a type 347 austenitic stainless steel. Scr Mater 52:675–678CrossRef

Laha K, Kyono J, Shinya N (2007) An advanced creep cavitation resistance Cu-containing 18Cr–12Ni–Nb austenitic stainless steel. Scr Mater 56:915–918CrossRef

Laha K, Kyono J, Shinya N (2007) Some chemical and microstructural factors influencing creep cavitation resistance of austenitic stainless steels. Philos Mag 87:2483–2505CrossRef

Laha K, Kyono J, Shinya N (2011) Copper, boron, and cerium additions in type 347 austenitic steel to improve creep rupture strength. Metall Mater Trans A 43A:1187–1197

He SM, van Dijk NH, Schut H, Peekstok ER, van der Zwaag S (2010) Thermally activated precipitation at deformation-induced defects in Fe–Cu and Fe–Cu–B–N alloys studied by positron annihilation spectroscopy. Phys Rev B 81:094103–1–094103–10

He SM, van Dijk NH, Paladugu M, Schut H, Kohlbrecher J, Tichelaar FD, van der Zwaag S (2010) In situ determination of aging precipitation in deformed Fe–Cu and Fe–Cu–B–N alloys by time-resolved small-angle neutron scattering. Phys Rev B 82:174111–1–174111–14

He SM, Brandhoff PN, Schut H, van der Zwaag S, van Dijk NH (2013) Positron annihilation study on repeated deformation/precipitation aging in Fe–Cu–B–N alloys. J Mater Sci 48:6150–6156. doi:10.1007/s10853-013-7411-9 CrossRef

Hornbogen E (1962) The role of strain energy during precipitation of copper and gold from alpha iron. Acta Metall 10:525–533CrossRef

Higgins Wilkes P (1972) Precipitation in the Fe–Mo and Fe–Au systems. Philos Mag 25:599–623CrossRef

10.

Ricks RA (1981) A comparative study of precipitation at interphase boundaries in Fe–Cu–Ni and Fe–Au–Ni alloys. J Mater Sci 16:3006–3012. doi:10.1007%2FBF00540305 CrossRef

11.

Zhang S, Kohlbrecher J, Tichelaar FD, Langelaan G, Brück E, van der Zwaag S, van Dijk NH (2013) Defect-induced Au precipitation in Fe–Au and Fe–Au–B–N alloys studied by in situ small-angle neutron scattering. Acta Mater 61:7009–7019CrossRef

12.

Zhang S, Langelaan G, Brouwer JC, Sloof WG, Brück E, van der Zwaag S, van Dijk NH (2014) Preferential Au precipitation at deformation-induced defects in Fe–Au and Fe–Au–B–N alloys. J Alloys Compd 584:425–429CrossRef

13.

Asoka-Kumar P, Alatalo M, Ghosh VJ, Kruseman AC, Nielsen B, Lynn KG (1996) Increased elemental specificity of positron annihilation spectra. Phys Rev Lett 77:2097–2100CrossRef

14.

Vrátná J, Janeček M, Čížek J, Lee DJ, Yoon EY, Kim HS (2013) Mechanical properties and microstructure evolution in ultrafine-grained AZ31 alloy processed by severe plastic deformation. J Mater Sci 48:4705–4712. doi:10.1007/s10853-013-7151-x CrossRef

15.

Janeček M, Čížek J, Gubicza J, Vrátná J (2012) Microstructure and dislocation density evolution in MgAlZn alloy processed by severe plastic deformation. J Mater Sci 47:7860–7869. doi:10.1007/s10853-012-6538-4 CrossRef

16.

Nagai Y, Hasegawa M, Tang Z, Hempel A, Yubuta K, Shimamura T et al (2000) Positron confinement in ultrafine embedded particles: quantum-dot-like state in an Fe–Cu alloy. Phys Rev B 61:6574–6578CrossRef

17.

Hasegawa M, Tang Z, Nagai Y, Chiba T, Kuramoto E, Takenaka M (2005) Irradiation-induced vacancy and Cu aggregations in Fe–Cu model alloys of reactor pressure vessel steels: state-of-the-art positron annihilation spectroscopy. Philos Mag 85:467–478CrossRef

18.

Nagai Y, Takadate K, Tang Z, Ohkubo H, Sunaga H, Takizawa H, Hasegawa M (2003) Positron annihilation study of vacancy–solute complex evolution in Fe-based alloys. Phys Rev B 67:224202–1–224202–6CrossRef

19.

Onitsuka T, Takenaka M, Kuramoto E, Nagai Y, Hasegawa M (2001) Deformation-enhanced Cu precipitation in Fe–Cu alloy studied by positron annihilation spectroscopy. Phys Rev B 65:012204–1–012204–4CrossRef

20.

Xu J, Mills AP Jr, Ueda A, Henderson DO, Suzuki R, Ishibashi S (1999) Vacancy clusters on surfaces of Au nanoparticles embedded in MgO. Phys Rev Lett 83:4586–4589CrossRef

21.

Bečvář F, Čížek J, Procházka I, Janotová J (2005) The asset of ultra-fast digitizers for positron-lifetime spectroscopy. Nucl Instr Meth Phys Res A 539:372–385CrossRef

22.

Puska M, Lanki P, Nieminen RM (1989) Positron affinities for elemental metals. J Phys 1:6081–6093

23.

Nagai Y, Tang Z, Hassegawa M, Kanai T, Saneyasu M (2001) Irradiation-induced Cu aggregations in Fe: an origin of embrittlement of reactor pressure vessel steels. Phys Rev B 63:134110–1–134110–5CrossRef

24.

Brusa RS, Deng W, Karwasz GP, Zecca A (2002) Doppler-broadening measurements of positron annihilation with high-momentum electrons in pure elements. Nucl Instr Meth Phys Res B 194:519–531CrossRef

25.

Topolsky J, Chuang SY, Tao SJ (1976) Positron lifetimes in heat treated and plastically deformed iron. Phys Status Solidi (A) 35:K17–K22CrossRef

26.

Čížek J, Procházka I, Kočík J, Keilová E (2000) Positron lifetime study of reactor pressure vessel steess. Phys Status Solidi (A) 178:651–662CrossRef

27.

Park Y-K, Waber JT, Meshii M, Snead CL Jr, Park CG (1986) Dislocation studies on deformed single crystals of high-purity iron using positron annihilation: determination of dislocation densities. Phys Rev B 34:823–836CrossRef

28.

West RN (1979) Positron studies of lattice defects in metal. In: Hautojärvi P (ed) Positrons in solids. Springer, Berlin Heidelberg, pp 89–144CrossRef

29.

Hidalgo C, González-Doncel G, Linderoth S, Juan JS (1992) Structure of dislocations in Al and Fe as studied by positron-annihilation spectroscopy. Phys Rev B 45:7017–7021CrossRef

30.

Shirai Y, Matsumoto K, Kawaguchi G, Yamaguchi M (1992) Systematic change in positron lifetime with the magnitude of burgers vectors of dislocations in metals. Mater Sci Forum 105–110:1225–1228CrossRef

31.

Vehanen A, Hautojärvi P, Johansson J, Yli-Kauppila J, Moser P (1982) Vacancies and carbon impurities in α-iron: electron irradiation. Phys Rev B 25:762–780CrossRef

32.

Hautojärvi P, Johansson J, Vehanen A, Yli-Kauppila J, Moser P (1980) Vacancy-carbon interation in iron. Phys Rev Lett 44:1326–1329CrossRef

33.

Hall TM, Goland AN, Snead CL Jr (1974) Applications of positron-lifetime measurements to the study of defects in metals. Phys Rev B 10:3062–3074CrossRef

34.

Shirai Y, Furukawa K, Takamura J, Yamada W, Iwata S (1985) Nucleation process of stacking fault tetrahedral in gold studied by positron lifetime spectroscopy. Appl Phys A 37:65–72CrossRef

35.

Cottrell AH, Bilby BA (1949) Dislocation theory of yielding and strain ageing of iron. Proc Phys Soc A 62:49–62CrossRef

Titel: Positron annihilation study on deformation-induced Au precipitation in Fe–Au and Fe–Au–B–N alloys
verfasst von: S. Zhang
H. Schut
J. Čížek
F. D. Tichelaar
E. Brück
S. van der Zwaag
N. H. van Dijk
Publikationsdatum: 01.03.2014
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 6/2014
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-013-7946-9

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