Phase-field simulations of gas density within bubbles in metals under irradiation

Paul C. Millett; Michael Tonks

doi:10.1016/j.commatsci.2011.02.006

Phase-field simulations of gas density within bubbles in metals under irradiation

Paul C. Millett, Michael Tonks

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

Phase-field simulations are used to study the evolution of gas density within irradiation-induced bubbles in solids. In our simulations, which use copper as a model material, the dpa rate, gas production rate, and defect diffusivities are systematically varied to understand their effect on bubble nucleation rates, bubble densities, and the distribution of gas concentration within bubbles and in the solid regions. We find that gas densities within bubbles fluctuate drastically in the early nucleation stages, when growth rates are highest, but converge to steady-state values during the later coarsening stages. The steady-state gas densities within bubbles correspond with the ratio of total accumulated vacancy content divided by the total accumulated gas content, in agreement with a thermodynamic analysis concerning free-energy minimization.

Original language	English (US)
Pages (from-to)	2044-2050
Number of pages	7
Journal	Computational Materials Science
Volume	50
Issue number	7
DOIs	https://doi.org/10.1016/j.commatsci.2011.02.006
State	Published - May 2011

All Science Journal Classification (ASJC) codes

General Computer Science
General Chemistry
General Materials Science
Mechanics of Materials
General Physics and Astronomy
Computational Mathematics

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10.1016/j.commatsci.2011.02.006

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title = "Phase-field simulations of gas density within bubbles in metals under irradiation",

abstract = "Phase-field simulations are used to study the evolution of gas density within irradiation-induced bubbles in solids. In our simulations, which use copper as a model material, the dpa rate, gas production rate, and defect diffusivities are systematically varied to understand their effect on bubble nucleation rates, bubble densities, and the distribution of gas concentration within bubbles and in the solid regions. We find that gas densities within bubbles fluctuate drastically in the early nucleation stages, when growth rates are highest, but converge to steady-state values during the later coarsening stages. The steady-state gas densities within bubbles correspond with the ratio of total accumulated vacancy content divided by the total accumulated gas content, in agreement with a thermodynamic analysis concerning free-energy minimization.",

author = "Millett, {Paul C.} and Michael Tonks",

note = "Funding Information: The authors gratefully acknowledge insightful conversations with Anter El-Azab, as well as financial support from the Nuclear Energy Modeling and Simulation (NEAMS) program within the US Department of Energy. ",

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AU - Millett, Paul C.

AU - Tonks, Michael

N1 - Funding Information: The authors gratefully acknowledge insightful conversations with Anter El-Azab, as well as financial support from the Nuclear Energy Modeling and Simulation (NEAMS) program within the US Department of Energy.

PY - 2011/5

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N2 - Phase-field simulations are used to study the evolution of gas density within irradiation-induced bubbles in solids. In our simulations, which use copper as a model material, the dpa rate, gas production rate, and defect diffusivities are systematically varied to understand their effect on bubble nucleation rates, bubble densities, and the distribution of gas concentration within bubbles and in the solid regions. We find that gas densities within bubbles fluctuate drastically in the early nucleation stages, when growth rates are highest, but converge to steady-state values during the later coarsening stages. The steady-state gas densities within bubbles correspond with the ratio of total accumulated vacancy content divided by the total accumulated gas content, in agreement with a thermodynamic analysis concerning free-energy minimization.

AB - Phase-field simulations are used to study the evolution of gas density within irradiation-induced bubbles in solids. In our simulations, which use copper as a model material, the dpa rate, gas production rate, and defect diffusivities are systematically varied to understand their effect on bubble nucleation rates, bubble densities, and the distribution of gas concentration within bubbles and in the solid regions. We find that gas densities within bubbles fluctuate drastically in the early nucleation stages, when growth rates are highest, but converge to steady-state values during the later coarsening stages. The steady-state gas densities within bubbles correspond with the ratio of total accumulated vacancy content divided by the total accumulated gas content, in agreement with a thermodynamic analysis concerning free-energy minimization.

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Phase-field simulations of gas density within bubbles in metals under irradiation

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