Your search keyword '"Kamboj, Anshul"' showing total 2 results

1. Dose and dose rate dependence of precipitation in a series of surveillance RPV steels under ion and neutron irradiation.

Author

Kamboj, Anshul, Almirall, Nathan, Yamamoto, Takuya, Tumey, Scott, Marquis, Emmanuelle A., and Odette, G. Robert

Subjects

*NEUTRON irradiation, *ATOM-probe tomography, *LIGHT water reactors, *PRECIPITATION hardening, *PRESSURE vessels, *COPPER

Abstract

Life extension of light water reactors requires robust models to predict the embrittlement of reactor pressure vessel (RPV) steels under long-term neutron irradiation. Embrittlement is due to nanoscale precipitation hardening by phases containing Cu, Mn, Ni, and Si, resulting in increases of the ductile to brittle transition temperature. Embrittlement data for low flux, high fluence extended life conditions, up to 80 years or more, are largely not available. Thus, higher flux, accelerated test reactor irradiations have been used to help develop models to predict low flux embrittlement at high fluence. Here flux, or dose rate, is expressed in units of displacements per atom per second (dpa/s). The dose rate can significantly influence precipitate evolution in a way that depends on fluence (dpa), temperature, and alloy composition, as well as flux itself. Here, we explore precipitation in surveillance steels with varying compositions at high fluxes (10−5–10−6 dpa/s) produced using 70 MeV Fe2+ ion irradiations. Atom probe tomography was used to characterize the dose dependence of precipitation at very high ion irradiation dose rates, and to evaluate corresponding similarities or differences compared to neutron irradiated steels at a much lower dose rate of ≈ 5 × 10−9 dpa/s. The data show that, on average, the ion irradiation precipitate volume fractions increase by factors of ∼ 1.5 to 2 between 0.3 dpa and 1.2 dpa. Limited data show that the major effect of neutron versus ion irradiation is the former has lower precipitate number densities and larger sizes. Otherwise, the precipitates are remarkably similar in composition and volume fraction. [ABSTRACT FROM AUTHOR]

Published

2024

2. The effect of phosphorus on precipitation in irradiated reactor pressure vessel (RPV) steels.

Author

Kamboj, Anshul, Bachhav, Mukesh N, Dubey, Megha, Almirall, Nathan, Yamamoto, Takuya, Marquis, Emmanuelle A, and Odette, G. Robert

Subjects

*PRESSURE vessels, *ATOM-probe tomography, *LIGHT water reactors, *NEUTRON irradiation, *COPPER

Abstract

Embrittlement of light water reactor pressure vessel (RPV) steels by fast neutron irradiation may limit extended nuclear plant life. Embrittlement, which is manifested as increases in various indexes of a ductile to brittle transition temperatures (ΔT), is primarily due to hardening by nanoscale precipitates containing Cu, Ni, Mn, and Si, which form under irradiation. In addition to these elements, P has also been found to play a role in embrittlement. While only slightly enriched in the precipitates, hardening and embrittlement increase with trace P concentrations in low-Cu steels. Here, we characterize the individual and synergistic irradiation precipitation and hardening mechanisms in a series of RPV steels containing no to low-Cu and with systematic variations in Ni and P. The steels were irradiated to a fluence of ∼ 1.38×1020 n/cm2 at ∼ 292 °C in the UCSB ATR-2 experiment. In nominally Cu-free medium and high-Ni RPV steels, atom probe tomography shows that P and Ni promote precipitation of P-Mn-Si-Ni and Mn-Si-Ni precipitates, respectively. The precipitate microstructure correlates with the observed irradiation hardening. [ABSTRACT FROM AUTHOR]

Published

2023