Abstract

Bentonite is used as a buffer material in most high-level radioactive waste (HLW) repository designs. Smectite clay is the main mineral component of bentonite and plays a key role in controlling the buffer’s physical and chemical behaviors. Moreover, the long-term functions of buffer clay could be lost through smectite dehydration under the prevailing temperature stemming from the heat of waste decay. Therefore, the influence of waste decay temperatures on bentonite performance needs to be studied. However, seldom addressed is the influence of the thermo-hydro-chemical (T-H-C) processes on buffer material degradation in the engineered barrier system (EBS) of HLW disposal repositories as related to smectite clay dehydration. Therefore, we adopted the chemical kinetic model of smectite dehydration to calculate the amount of water expelled from smectite clay minerals caused by the higher temperatures of waste decay heat. We determined that the temperature peak of about 91.3 °C occurred at the junction of the canister and buffer material in the sixth year. After approximately 20,000 years, the thermal caused by the release of the canister had dispersed and the temperature had reduced close to the geothermal background level. The modified porosity of bentonite due to the temperature evolution in the buffer zone between 0 and 0.01 m near the canister was 0.321 (1–2 years), 0.435 (3–10 years), and 0.321 (11–20,000 years). In the buffer zone of 0.01–0.35 m, the porosity was 0.321 (1–20,000 years). In the simulation results of near-field radionuclide transport, we determined that the concentration of radionuclides released from the buffer material for the porosity of 0.321 was higher than that for the unmodified porosity of 0.435. It occurs after 1, 1671, 63, and 172 years for the I-129, Ni-59, Sr-90, and Cs137 radionuclides, respectively. The porosity correction model proposed herein can afford a more conservative concentration and approach to the real release concentration of radionuclides, which can be used for the safety assessment of the repository. Smectite clay could cause volume shrinkage because of the interlayer water loss in smectite and cause bentonite buffer compression. Investigation of the expansion pressure of smectite and the confining stress of the surrounding host rock can further elucidate the compression and volume expansion of bentonite. Within 10,000 years, the proportion of smectite transformed to illite is less than 0.05%. The decay heat temperature in the buffer material should be lower than 100 °C, which is a very important EBS design condition for radioactive waste disposal. The results of this study may be used in advanced research on the evolution of bentonite degradation for both performance assessments and safety analyses of final HLW disposal.

Highlights

  • The safety concept of a geological repository for the disposal of radioactive waste is based on a multibarrier system that includes the natural geological barrier and engineered barrier system (EBS) [1]

  • This study adopted the chemical kinetic model of smectite dehydration to calculate the amount of water expelled from smectite clay minerals because of higher temperatures of waste decay heat

  • The further required characteristic is that the buffer material must be chemically compatible with the canister material and the surrounding host rock with its groundwater chemical species, and that it must be mainly inorganic to eliminate the risk of producing organic colloids that can carry radionuclides or create new forms of life [6]

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Summary

Introduction

The safety concept of a geological repository for the disposal of radioactive waste is based on a multibarrier system that includes the natural geological barrier and engineered barrier system (EBS) [1]. The embedded clay must be used to protect canisters from mechanical impact and must be very taut and almost free of groundwater permeation These are the primary objectives of the buffer zone, and preventing the migration of discharging radionuclides is a secondary objective. Literature indicates that the thermal-hydraulic-mechanical (THM) model, which is used to predict the soil mechanical properties of the buffer zone, states that the final density will be uneven, which has been verified by field tests. This is because internal friction prevents the initial, very significant density difference [6,7]

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