Positron annihilation spectroscopy and small angle neutron scattering characterization of nanostructural features in high-nickel model reactor pressure vessel steels

Abstract Irradiation embrittlement in nuclear reactor pressure vessel steels results from the hardening by a high number density of nanometer scale features. In steels with more than ≈0.10% Cu, the dominant features are often Cu-rich precipitates typically alloyed with Mn, Ni and Si. At low-Cu and low-to-intermediate Ni levels, so-called matrix hardening features are believed to be vacancy-solute cluster complexes, or their remnants. However, Mn–Ni–Si rich precipitates, with Mn plus Ni contents greater than Cu, can form at high alloy Ni contents and are promoted at irradiation temperatures lower than the nominal 290 °C. Even at very low-Cu levels, late blooming Mn–Ni–Si rich precipitates are a significant concern due to their potential to form large volume fractions of hardening features. Positron annihilation spectroscopy (PAS) and small angle neutron scattering neutron (SANS) measurements were used to characterize the fine-scale microstructure in split-melt A533B steels with varying Ni and Cu contents, irradiated at selected conditions from 270 to 310 °C between ≈0.04 and 1.6 × 10 23  n m −2 . The objective was to assess the character, composition and magnetic properties of Cu-rich precipitates, as well as to gain insight on the matrix features. The results suggest that the irradiated very low-Cu and intermediate Ni steel contains small vacancy-Mn–Ni–Si cluster complexes, but not large, well-formed and highly enriched Mn–Ni–Si phases. The hardening features in steels containing 0.2% and 0.4% Cu, and 0.8% and 1.6% Ni are consistent with well-formed, non-magnetic Cu–Ni–Mn precipitates. The precipitate number densities and volume fractions increase, while their sizes decrease, with increasing Ni and decreasing irradiation temperature. The precipitates evolve with fluence in stages of nucleation, growth and limited coarsening.

[1]  Lynn,et al.  Increased Elemental Specificity of Positron Annihilation Spectra. , 1996, Physical review letters.

[2]  B. Radiguet,et al.  Influence of electron irradiation on the microstructure of ferritic model alloys , 2004 .

[3]  T. Tobita,et al.  Radiation enhanced copper clustering processes in Fe-Cu alloys during electron and ion irradiations as measured by electrical resistivity , 2003 .

[4]  G. E. Lucas,et al.  Recent progress in understanding reactor pressure vessel steel embrittlement , 1998 .

[5]  J. M. Rowe,et al.  The small‐angle neutron scattering spectrometer at the National Bureau of Standards , 1986 .

[6]  Risto M. Nieminen,et al.  Theory of Positrons in Solids and on Solid Surfaces , 1994 .

[7]  Luigi Debarberis,et al.  A preliminary evaluation of irradiation damage in model alloys by electric properties based techniques , 2005 .

[8]  Andrew G. Glen,et al.  APPL , 2001 .

[9]  Michael K Miller,et al.  Understanding Pressure Vessel Steels: An Atom Probe Perspective , 2000 .

[10]  N. B. Smirnov,et al.  Fast neutron irradiation effects in n-GaN , 2007 .

[11]  G. Odette On the dominant mechanism of irradiation embrittlement of reactor pressure vessel steels , 1983 .

[12]  B. Wirth,et al.  Precipitation in neutron-irradiated Fe-Cu and Fe-Cu-Mn model alloys : a comparison of APT and SANS data , 2003 .

[13]  T. Yamamoto,et al.  On the effect of dose rate on irradiation hardening of RPV steels , 2005 .

[14]  M. G. Burke,et al.  An atom probe field ion microscopy study of neutron-irradiated pressure vessel steels , 1992 .

[15]  P. Pareige,et al.  Synthesis of atom probe experiments on irradiation-induced solute segregation in French ferritic pressure vessel steels , 2000 .

[16]  Y. Kawazoe,et al.  Positron confinement in ultrafine embedded particles: Quantum-dot-like state in an Fe-Cu alloy , 2000 .

[17]  Brian D. Wirth,et al.  A computational microscopy study of nanostructural evolution in irradiated pressure vessel steels , 1997 .

[18]  B. Wirth,et al.  Positron annihilation spectroscopy and small-angle neutron scattering characterization of the effect of Mn on the nanostructural features formed in irradiated Fe–Cu–Mn alloys , 2005 .

[19]  M. Kakihana,et al.  Materials Research Society Symposium - Proceedings , 2000 .

[20]  Roger E. Stoller,et al.  Influence of long-term thermal aging on the microstructural evolution of nuclear reactor pressure vessel materials: an atom probe study , 1997 .

[21]  Brian D. Wirth,et al.  Multiscale-Multiphysics Modeling of Radiation-Damaged Materials: Embrittlement of Pressure-Vessel Steels , 2001 .

[22]  Y. Nagai,et al.  Irradiation-induced vacancy and Cu aggregations in Fe–Cu model alloys of reactor pressure vessel steels: state-of-the-art positron annihilation spectroscopy , 2005 .

[23]  B. Wirth,et al.  A lattice Monte Carlo simulation of nanophase compositions and structures in irradiated pressure vessel Fe-Cu-Ni-Mn-Si steels , 1997 .

[24]  Yasuyoshi Nagai,et al.  Irradiation-induced Cu aggregations in Fe: An origin of embrittlement of reactor pressure vessel steels , 2001 .

[25]  G. S. Was *,et al.  Hardening and microstructure evolution in proton-irradiated model and commercial pressure-vessel steels , 2005 .

[26]  B. Wirth,et al.  Composition and magnetic character of nanometre-size Cu precipitates in reactor pressure vessel steels: Implications for nuclear power plant lifetime extension , 2002 .

[27]  G. E. Lucas,et al.  Embrittlement of nuclear reactor pressure vessels , 2001 .