Journal article
Development of an ERT‐Based Framework for Bentonite Buffers Monitoring From Laboratory Tests: 1. Characterizing Thermal–Hydrological–Mechanical Processes
Journal of geophysical research. Solid earth, Vol.130(8), p.n/a
08/2025
DOI: 10.1029/2024JB030798
Abstract
Bentonite clay is widely used in engineered barrier systems for the permanent disposal of high‐level radioactive waste due to its low permeability, high swelling capacity, and thermal stability. However, the complex thermal‐hydrological‐mechanical (THM) processes induced by heating from decaying radioactive waste and hydration from surrounding rock can lead to heterogeneous changes that are difficult to measure and predict. This study develops an Electrical Resistivity Tomography (ERT)‐based framework for monitoring THM processes, progressing from sample‐scale to bench‐scale tests, to inform field‐scale applications. Sample‐scale tests analyzed small bentonite samples under controlled variations in water content, temperature, and porosity to establish fundamental resistivity relationships. Bench‐scale tests involved larger bentonite columns subjected to heating (up to 200°C) and hydration under controlled pressure, simulating repository conditions. ERT measurements, complemented by X‐ray CT imaging, temperature monitoring, and tracing sensors, revealed coupled THM processes, such as hydration‐induced compression, swelling, and thermal gradients, leading to complex resistivity patterns. The results demonstrate the potential of ERT for capturing THM‐induced resistivity changes, though challenges remain in upscaling and quantitative analysis. This study evaluates laboratory test capabilities and proposes future improvements for understanding THM‐induced resistivity responses. A conceptual framework for ERT implementation in field‐scale monitoring is presented, synthesizing findings from both scales and exploring how ERT data can inform long‐term modeling and reduce prediction uncertainties. Overall, this ERT‐based framework offers a robust method for monitoring bentonite buffers, aiding in early issue detection and supporting the safe long‐term disposal of radioactive waste in geological repositories, while highlighting the need for future development.
Plain Language Summary
Bentonite clay is crucial in engineered barrier systems (EBS) for containing high‐level radioactive waste due to its ability to absorb water, swell, seal and remain stable under high temperatures. When bentonite absorbs water and heats up from radioactive decay, it experiences complex changes in its physical and mechanical properties. Understanding these changes is important for ensuring the long‐term safety and effectiveness of EBS. This study used Electrical Resistivity Tomography (ERT), a non‐invasive method that measures electrical conductivity to monitor these changes during laboratory experiments. The ERT data revealed significant variations in resistivity corresponding to changes in water content, temperature, and density, providing detailed spatial and temporal insights into the behavior of bentonite. These findings enhance our ability to predict the long‐term performance of bentonite barriers, ensuring the safe containment of radioactive waste. By improving our understanding of bentonite's behavior, this research supports the development of more reliable and effective barrier systems for radioactive waste disposal, protecting the environment and public health.
Key Points
ERT monitoring was employed to capture resistivity changes in bentonite during controlled heating and hydration experiments, providing insights into THM processes
ERT data reveal significant resistivity changes correlated with water content, temperature, and mechanical effects, enhancing the understanding of THM dynamics in bentonite
This study explores the potential of the framework for application in field‐scale EBS monitoring, emphasizing the need for integrating additional geophysical methods for comprehensive subsurface imaging
Details
- Title: Subtitle
- Development of an ERT‐Based Framework for Bentonite Buffers Monitoring From Laboratory Tests: 1. Characterizing Thermal–Hydrological–Mechanical Processes
- Creators
- Hang Chen - Lawrence Berkeley National LaboratoryChunwei Chou - Lawrence Berkeley National LaboratoryLuca Peruzzo - Lawrence Berkeley National LaboratorySharon Borglin - Lawrence Berkeley National LaboratoryChun Chang - Lawrence Berkeley National LaboratoryToshiyuki Bandai - Lawrence Berkeley National LaboratoryTimothy Kneafsey - Lawrence Berkeley National LaboratorySeiji Nakagawa - Lawrence Berkeley National LaboratoryJens Birkholzer - Lawrence Berkeley National LaboratoryLiange Zheng - Lawrence Berkeley National LaboratoryYuxin Wu - Lawrence Berkeley National Laboratory
- Resource Type
- Journal article
- Publication Details
- Journal of geophysical research. Solid earth, Vol.130(8), p.n/a
- DOI
- 10.1029/2024JB030798
- ISSN
- 2169-9313
- eISSN
- 2169-9356
- Number of pages
- 22
- Grant note
- Office of Nuclear Energy (DE‐AC02‐05CH11231)
- Language
- English
- Date published
- 08/2025
- Academic Unit
- Earth and Environmental Sciences
- Record Identifier
- 9984962533002771
Metrics
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