Role of the geosphere in deep nuclear waste disposal – An England and Wales perspective

Abstract

To dispose permanently of its higher activity nuclear waste England and Wales have chosen deep geological disposal as the most appropriate solution currently available. The purpose of this paper is to describe the main geological features, events and processes relevant to England and Wales that will need to be considered to demonstrate that a site is suitable for a geological disposal facility (GDF). England and Wales are in the early stages of a GDF siting process in which areas of interest are being evaluated using mainly existing data from surface mapping and hydrocarbon exploration and production. Sites are evaluated consistently under six overarching headings, three of which are impacted by their geological setting – safety, engineering feasibility and value for money. “Suitable” geology is that which is safe during the operational and long-term post-closure period, which could have a GDF and its accessways constructed within it, and which delivers value for money. A GDF needs to fulfil dual safety functions wherever it is located: long-term containment of radionuclides, and isolation of the waste from human actions and from natural processes such as glaciations and earthquakes. The role of the geosphere in delivering these safety functions is to provide a low-flux groundwater environment with geochemical conditions that minimise degradation of the engineered components of the GDF, to promote retention of mobilised radionuclides, and to protect the waste from the impacts of humans and natural processes. The containment function of a GDF is provided by a combination of rock and engineering generally referred to as the multibarrier system. It comprises the engineered barriers – solid wasteforms, canisters, buffers, backfill materials, plugs and seals – that work together with the rock to ensure long-term containment. The GDF Programme in England and Wales seeks to identify suitable geological environments for which bespoke engineered barriers can be tailored to optimize the performance of the multibarrier system. The post-closure period over which independent regulators will require a safety case to demonstrate the long-term containment and isolation capabilities of a GDF is up to 1 million years. The long timescales make post-closure safety assessments a unique feature of deep geological disposal programmes. A comprehensive site characterization programme will use information mostly from seismic surveying and deep investigation boreholes to establish adequate rock availability (host rock depth, thickness, areal extent and compartmentalisation), suitable properties and behaviour of the deep geological environment, and the constructability and operability of a potential GDF site including its surface to subsurface access ways. Nuclear Waste Services, the organisation tasked with developing a GDF in England and Wales, is currently engaged with four Community Partnerships through a volunteer siting process: three in west Cumbria, and one on the English east coast in Theddlethorpe, Lincolnshire. In all of these areas Mesozoic claystones have been provisionally identified as potentially suitable GDF host rocks and are being investigated further, with a dedicated 3D seismic survey acquired off the coast of Cumbria in 2022. The main conclusion to be drawn from this paper is that a GDF could be sited in a large number of geological settings in England and Wales, and that the success of the current siting process will largely depend on engaging effectively with willing communities and building enduring relationships with them.