E. Getto scite author profile

a b s t r a c tThe effects of transmutation produced helium and hydrogen must be included in ion irradiation experiments to emulate the microstructure of reactor irradiated materials. Descriptions of the criteria and systems necessary for multiple ion beam irradiation are presented and validated experimentally. A calculation methodology was developed to quantify the spatial distribution, implantation depth and amount of energy-degraded and implanted light ions when using a thin foil rotating energy degrader during multi-ion beam irradiation. A dual ion implantation using 1.34 MeV Fe + ions and energy-degraded D + ions was conducted on single crystal silicon to benchmark the dosimetry used for multi-ion beam irradiations. Secondary Ion Mass Spectroscopy (SIMS) analysis showed good agreement with calculations of the peak implantation depth and the total amount of iron and deuterium implanted. The results establish the capability to quantify the ion fluence from both heavy ion beams and energy-degraded light ion beams for the purpose of using multi-ion beam irradiations to emulate reactor irradiated microstructures.

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The co-evolution of microstructure features in self-ion irradiated HT9 at very high damage levels

Getto

VanCoevering

Was

2017

Journal of Nuclear Materials

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Understanding the void swelling and phase evolution of reactor structural materials at very high damage levels is essential to maintaining safety and longevity of components in Gen IV fast reactors. A combination of ion irradiation and modeling was utilized to understand the microstructure evolution of ferritic-martensitic alloy HT9 at high dpa. Self-ion irradiation experiments were performed on alloy HT9to determine the co-evolution of voids, dislocations and precipitates up to 650 dpa at 460°C. Modeling of microstructure evolution was conducted using the modified Radiation Induced Microstructure Evolution (RIME) model, which utilizes a mean field rate theory approach with grouped cluster dynamics.Irradiations were performed with 5 MeV raster-scanned Fe 2+ ions on samples pre-implanted with 10 atom parts per million He. The swelling, dislocation and precipitate evolution at very high dpa was determined using Analytical Electron Microscopy in Scanning Transmission Electron Microscopy (STEM) mode.Experimental results were then interpreted using the RIME model. A microstructure consisting only of dislocations and voids is insufficient to account for the swelling evolution observed experimentally at high damage levels in a complicated microstructure such as irradiated alloy HT9. G phase was found to have a minimal effect on either void or dislocation evolution. M 2 X plays two roles; a variable biased sink for defects, and as a vehicle for removal of carbon from solution, thus promoting void growth. When accounting for all microstructure interactions, swelling at high damage levels is a dynamic process that continues to respond to other changes in the microstructure as long as they occur.

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In situ tensile study of PM-HIP and wrought 316 L stainless steel and Inconel 625 alloys with high energy diffraction microscopy

Guillen¹,

Pagan²,

Getto³

et al. 2018

Materials Science and Engineering: A

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E. Getto

Emulation of reactor irradiation damage using ion beams

Void swelling and microstructure evolution at very high damage level in self-ion irradiated ferritic-martensitic steels

Effect of pre-implanted helium on void swelling evolution in self-ion irradiated HT9

Effect of irradiation mode on the microstructure of self-ion irradiated ferritic-martensitic alloys

Methodology for determining void swelling at very high damage under ion irradiation

Multiple ion beam irradiation for the study of radiation damage in materials

The co-evolution of microstructure features in self-ion irradiated HT9 at very high damage levels

In situ tensile study of PM-HIP and wrought 316 L stainless steel and Inconel 625 alloys with high energy diffraction microscopy

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E. Getto

Emulation of reactor irradiation damage using ion beams

Void swelling and microstructure evolution at very high damage level in self-ion irradiated ferritic-martensitic steels

Effect of pre-implanted helium on void swelling evolution in self-ion irradiated HT9

Effect of irradiation mode on the microstructure of self-ion irradiated ferritic-martensitic alloys

Methodology for determining void swelling at very high damage under ion irradiation

Multiple ion beam irradiation for the study of radiation damage in materials

The co-evolution of microstructure features in self-ion irradiated HT9 at very high damage levels

In situ tensile study of PM-HIP and wrought 316 L stainless steel and Inconel 625 alloys with high energy diffraction microscopy

Contact Info

Product

Resources

About

In situ tensile study of PM-HIP and wrought 316 L stainless steel and Inconel 625 alloys with high energy diffraction microscopy