Estimation of Effective Diffusivity in Compacted Ben Tonite

H. Kato; M. Muroi; N. Yamada; H. Ishida; H. Sato

doi:10.1557/PROC-353-277

Abstract

Effective diffusivities of radioactive nuclides in compacted bentonite were calculated theoretically by using an electric double layer theory. Comparison between calculated diffusivities and measured ones show good agreements.

The effective diffusivity is dominated by pore structure and pore diffusivity Dp. The pore structure can be characterized by effective porosity ε eff, constrictivity δ, and tortuosity Γ. The δ was assumed to be unity. The ε eff and the Γ were determined experimentally. The Dp was estimated by means of the electric double layer theory. In the estimation, smectite interlayer was assumed the space between parallel plane sheets of smectite crystal lattice.

Diffusion experiments were carried out by using Cs+ for monovalent cation, C1- and Tc04- for monovalent anion, and tritiated water for neutral molecule. The measured and calculated effective diffusivities in different densities showed the same tendency of cation > neutral > anion. The dry density of bentonite became higher, the discrepancy between the estimated and the measured diffusivities became larger. The calculation was limited by the applicability of the electric double layer theory in the near surface region of smectite.

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Estimation of Effective Diffusivity in Compacted Ben Tonite

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

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Estimation of Effective Diffusivity in Compacted Ben Tonite

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