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Autori principali: AbdulHameed, Mohamed, Mahbuba, Khadija, Yaseen, Mahmoud, Ibrahim, Amr, Moneghan, Daniel, Beeler, Benjamin
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.14325
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author AbdulHameed, Mohamed
Mahbuba, Khadija
Yaseen, Mahmoud
Ibrahim, Amr
Moneghan, Daniel
Beeler, Benjamin
author_facet AbdulHameed, Mohamed
Mahbuba, Khadija
Yaseen, Mahmoud
Ibrahim, Amr
Moneghan, Daniel
Beeler, Benjamin
contents Silver released from TRISO fuel particles can migrate through the SiC layer and deposit on reactor components, posing radiation hazards and operational challenges. Despite numerous proposed mechanisms, the precise pathway of silver transport through intact 3C-SiC remains unresolved. We present a physics-informed model for estimating the effective diffusivity of silver in polycrystalline 3C-SiC. Molecular dynamics (MD) simulations yield diffusivities for {Σ3} and {Σ9} grain boundaries (GBs), while literature values are used for other GB types and the bulk. These are combined using a bounds-averaging approach accounting for distinct GB transport properties. Bayesian inference of experimental data provides credible intervals for effective Arrhenius parameters and reveals a correlation between activation energy and pre-exponential factor. Although the homogenized model captures GB-mediated transport mechanisms, it overpredicts silver diffusivity relative to experiments. To resolve this, a multiplicative correction based on reversible trapping at nano-pores is introduced. It is derived from first principles and is shown to reproduce observed transport behavior. Sensitivity analysis identified trap desorption energy and {Σ9} GB diffusivity as dominant factors influencing Ag transport. The resulting framework provides a mechanistic description of Ag transport suitable for integration into higher-scale fuel performance models.
format Preprint
id arxiv_https___arxiv_org_abs_2508_14325
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Modeling of silver transport in cubic SiC: Integrating molecular dynamics, bounds averaging, and uncertainty quantification
AbdulHameed, Mohamed
Mahbuba, Khadija
Yaseen, Mahmoud
Ibrahim, Amr
Moneghan, Daniel
Beeler, Benjamin
Materials Science
Silver released from TRISO fuel particles can migrate through the SiC layer and deposit on reactor components, posing radiation hazards and operational challenges. Despite numerous proposed mechanisms, the precise pathway of silver transport through intact 3C-SiC remains unresolved. We present a physics-informed model for estimating the effective diffusivity of silver in polycrystalline 3C-SiC. Molecular dynamics (MD) simulations yield diffusivities for {Σ3} and {Σ9} grain boundaries (GBs), while literature values are used for other GB types and the bulk. These are combined using a bounds-averaging approach accounting for distinct GB transport properties. Bayesian inference of experimental data provides credible intervals for effective Arrhenius parameters and reveals a correlation between activation energy and pre-exponential factor. Although the homogenized model captures GB-mediated transport mechanisms, it overpredicts silver diffusivity relative to experiments. To resolve this, a multiplicative correction based on reversible trapping at nano-pores is introduced. It is derived from first principles and is shown to reproduce observed transport behavior. Sensitivity analysis identified trap desorption energy and {Σ9} GB diffusivity as dominant factors influencing Ag transport. The resulting framework provides a mechanistic description of Ag transport suitable for integration into higher-scale fuel performance models.
title Modeling of silver transport in cubic SiC: Integrating molecular dynamics, bounds averaging, and uncertainty quantification
topic Materials Science
url https://arxiv.org/abs/2508.14325