Vitrified nuclear waste durability in complex natural environments
Reference Number
EP/S012400/1
Title
Vitrified nuclear waste durability in complex natural environments
Status
Completed
Energy Categories
Nuclear Fission and Fusion(Nuclear Fission, Nuclear supporting technologies)
Research Types
Basic and strategic applied research
Science and Technology Fields
PHYSICAL SCIENCES AND MATHEMATICS (Chemistry)
PHYSICAL SCIENCES AND MATHEMATICS (Metallurgy and Materials)
ENVIRONMENTAL SCIENCES (Earth Systems and Environmental Sciences)
PHYSICAL SCIENCES AND MATHEMATICS (Metallurgy and Materials)
ENVIRONMENTAL SCIENCES (Earth Systems and Environmental Sciences)
UKERC Cross Cutting Characterisation
Not Cross-cutting
Principal Investigator
Dr CL Thorpe
Engineering Materials
University of Sheffield
Engineering Materials
University of Sheffield
Award Type
Standard
Funding Source
EPSRC
Start Date
01 September 2019
End Date
31 December 2023
Duration
52 months
Total Grant Value
£401,078
Industrial Sectors
Energy
Region
Yorkshire & Humberside
Programme
Energy : Energy
Industrial Collaborator
Project Contact, US Department of Energy
Project Contact, Radioactive Waste Management Ltd.
Project Contact, The University of Manchester
Project Contact, Radioactive Waste Management Ltd.
Project Contact, The University of Manchester
Web Site
Objectives
Abstract
Understanding the long-term durability of nuclear waste glass in the subsurface is important in the UK and internationally as many countries intend to dispose of vitrified radioactive waste in underground geological disposal facilities. In order to ensure safe disposal, we need to be confident that radioactive elements will remain isolated and immobilised for sufficient time to allow radioactivity to decay to safe levels. There will be multiple barriers in place (e.g. a metal container and engineered backfill) to delay groundwater from reaching the nuclear waste glass but eventually contact with water is expected. Although there are a number of laboratory tests currently used to determine the rate of glass dissolution in water all accelerate corrosion by increasing the temperature, surface area, or both and give very different predictions depending on the test conditions. Laboratory tests are also performed under simplified, stable, sterile conditions and using deionised water taking no account of how changing geochemical conditions will affect glass corrosion rates. This fellowship will combine materials science, geochemistry and geomicrobiology to study how glass corrodes in real-time in dynamic complex natural environments. I will improve understanding of key factors affecting corrosion (temperature, groundwater geochemistry, saturation, and microbiology) using the Ballidon long duration experiment, where glass samples have been buried for nearly 50 years. To predict the durability of nuclear waste glass thousands of years into the future I will study simulant nuclear waste glass's in conditions relevant to UK and US disposal concepts. The result of this novel investigation will be to critically evaluate, and improve, upon durability tests for glass, to build an improved model of glass corrosion and to establish further long duration experiments to inform the safety case for geological disposal in the UK and abroad.
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Added to Database
15/10/21
