Atomistic and mesoscale simulations to determine effective diffusion coefficient of fission products in SiC

Jiang, Chao; Ke, Jia-Hong; Simon, Pierre; Jiang, Wen

doi:10.2172/1825508

Cited by 2 publications

(3 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…One is that these two slabs are parallel to each other (Figure 1A), while the other one is that they are perpendicular to each other (Figure 1B). For the first structure shown in Figure 1A, the effective diffusion coefficient along the X and Y direction can be described analytically as (Hart, 1957;Jiang et al, 2021)…”

Section: Two Slab Structures For Validationmentioning

confidence: 99%

“…Despite atomistic simulations can give the microscopic mechanism of H interacting with defects, they are hard to predict the effective diffusion coefficient at the microstructural scale due to the limited spatial and time scales. Several analytical models have been developed to estimate the effective diffusion coefficient of the diffusion component in microstructures (Maxwell, 1881;Hart, 1957;Bakker et al, 1995;Chen and Schuh, 2007;Moradi, 2015;Jiang et al, 2021). Maxwell-Garnett et al (Maxwell, 1881;Moradi, 2015) developed a model to predict the effect of the volume fraction of the second phase on the effective diffusion coefficient in a two-phase system.…”

Section: Introductionmentioning

confidence: 99%

“…direction are the same because of the symmetric structure. Two different solutions derived by Jiang et al based on Eqs 28, 29 are respectively expressed as(Jiang et al, 2021) …”

mentioning

confidence: 99%

See 2 more Smart Citations

The Effective Diffusion Coefficient of Hydrogen in Tungsten: Effects of Microstructures From Phase-Field Simulations

Xue²,

Hao³

et al. 2022

Front. Mater.

View full text Add to dashboard Cite

In this work, we propose an efficient numerical method to study the effects of microstructures on the effective diffusion coefficient of the diffusion component in materials. We take the diffusion of hydrogen (H) atoms in porous polycrystalline tungsten (W) as an example. The grain structures and irradiated void microstructures are generated by using the phase-field model. The effective diffusion coefficients of H in these microstructures are obtained by solving the steady-state diffusion equation, using a spectral iterative algorithm. We first validate our simulation code for calculating the effective diffusion coefficient by using three simple examples. We then investigate the effects of the grain morphology and porosity on the effective diffusion coefficient of H in W. Regardless of whether the grain boundary is beneficial to the diffusion of H or not, it is found that the effective diffusion coefficient of H along the elongated grain direction in columnar crystals is always greater than that in isometric crystals. The increase of the porosity can significantly decrease the effective diffusion coefficient of H from the simulations of the porous W. A correlation of converting the two-dimensional (2D) effective diffusion coefficient into three-dimensional (3D) in the porous and polycrystalline W is fitted by using our simulation data, respectively. Two fitted correlations can be used to predict the synergistic effect of the porosity and grain boundary on the effective diffusion coefficient of H in W. Consequently, our simulation results provide a good reference for understanding the influence of the complex microstructures on H diffusion, and may help to design W-based materials for the fusion reactor.

show abstract

Section: Two Slab Structures For Validationmentioning

confidence: 99%