Annealing behaviour of plastically deformed stainless steel 1.4307 studied by positron annihilation methods

• Autorzy: Dryzek E. , Sarnek M. , Siemek K.
• Konferencja: Proceedings of the 40th Polish Seminar on Positron Annihilation PSPA'2012, 13-14 June 2012, Kazimierz Dolny, Poland
• Języki publikacji: EN

Abstrakty

EN

Isochronal and isothermal annealing of stainless steel 1.4307 samples deformed by compression were investigated using Doppler broadening measurements of the annihilation line. We made an attempt to describe the obtained dependencies in terms of vacancy migration and sinking to the grain boundaries. The model assumed spherical grains with a homogeneous initial distribution of vacancies. The model was capable of following the isochronal annealing data quite accurately. However, the obtained activation energy of vacancy migration equal to 0.44 plus or minus 0.05 eV seemed too low. The isothermal annealing dependency was reproduced less precisely. The reason for this may be the presence of the alfa'-martensite particles in the samples, which can introduce additional defects seen by positrons in the temperature range in which the martensite reversion takes place.

Słowa kluczowe

EN

plastic deformation; positron annihilation; stainless steel

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2013
• Tom: Vol. 58, No. 1
• Strony: 215--219
• Opis fizyczny: BIbliogr. 15 poz., rys.

Twórcy

autor

Dryzek E.

autor

Sarnek M.

autor

Siemek K.

• Institute of Nuclear Physics, Polish Academy of Sciences (IFJ PAN), 152 Radzikowskiego Str., 31-342 Kraków, Poland, Tel.: +48 12 662 8370, Fax: +48 12 662 8458,

Bibliografia

• 1. Arunkumar J, Abhaya S, Rajaraman R et al. (2009) Defect recovery in proton irradiated Ti-modified stainless steel probed by positron annihilation. J Nucl Mater 384:245–248
• 2. Asoka-Kumar P, Hartley JH, Howell RH et al. (2002) Direct observation of carbon-decorated defects in fatigued type 304 stainless steel using positron annihilation spectroscopy. Acta Mater 50:1761–1770
• 3. Bunshah RF, Mehl RF (1953) The rate of propagation of martensite. Trans AIME 197:1251–1258
• 4. Dryzek J (1997) Migration of vacancies in deformed silver studied by positron annihilation. Mater Sci Forum 255/257:533–535
• 5. Dryzek J, Singleton D (2006) Implantation profile and linear absorption coefficients for positrons injected in solids from radioactive sources 22Na and 68Ge\68Ga. Nucl Instrum Methods Phys Res B 252:197–204
• 6. Dryzek J, Wesseling C, Dryzek E, Cleff B (1994) Migration of vacancies in stainless steel measured by positron annihilation. Mater Lett 21:209–214
• 7. Eckstein CB, Guimarães JRC (1984) Microstructure-property correlation in martensite-austenite mixtures. J Mater Sci 19;9:3043–3048
• 8. Gauster WB, Wampler WR, Johnes WB, van der Avyle JA (1979) Nondestructive examination of deformed steel and nickel by positron annihilation. In: Hasiguti RR, Fujiwara K (eds) Proc of 5th Int Conf on Positron Annihilation, Lake Yamanaka, Japan, pp 125–128
• 9. Holzwarth U, Barbieri A, Hansen-Ilzhöfer S, Schaaff P, Haaks M (2001) Positron annihilation studies on the migration of deformation induced vacancies in stainless steel AISI 316L. Appl Phys A 73:467–475
• 10. Hori K, Koike K, Oshima R (2005) Investigation of lattice defects in the early stage of fatigue in iron by positron annihilation techniques. Appl Surf Sci 242:304–312
• 11. Kamimura Y, Tsutsumi T, Kuramoto K (1995) Calculations of positron lifetimes in a jog and vacancies on an edge-dislocation line in Fe. Phys Rev B 52:879–885
• 12. Kamimura Y, Tsutsumi T, Kuramoto K (1997) Influence of dislocations on positron lifetimes in iron. J Phys Soc Jpn 66:3090–3096
• 13. Kansy J (1996) Microcomputer program for analysis of positron annihilation lifetime spectra. Nucl Instrum Methods A 374:235–244
• 14. Padilha AF, Plaut RL, Rios PR (2003) Annealing of cold-worked austenitic stainless steels. ISIJ Int 43:135–143
• 15. Vehanen A, Hautojärvi P, Johansson J, Yli-Kauppila J (1982) Vacancies and carbon impurities in α-iron: Electron irradiation. Phys Rev B 25:762–780