The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

Electrokinetic generation of iron-rich barriers in soils: realising the potential for nuclear site management and decommissioning

Electrokinetic generation of iron-rich barriers in soils: realising the potential for nuclear site management and decommissioning
Electrokinetic generation of iron-rich barriers in soils: realising the potential for nuclear site management and decommissioning

Following earlier field-scale pilot work on nuclear site materials in the late 2000s, there has recently been renewed research and industry interest in the application of electrokinetic technologies for nuclear site management and remediation in the UK. One relatively novel application of electrokinetics is the use of sacrificial steel electrodes (coupled with an in situ generated pH-Eh gradient in the treated material) to precipitate sub-surface iron-rich barriers for groundwater and/or leachate containment, which could be used to grout or contain contaminated fluids in the sub-surface on working nuclear sites or sites undergoing decommissioning. Here, we report previously unpublished data from two work programmes exploring the higher Technology Readiness Level (TRL) application of this electrokinetic iron-barrier approach to materials typical of those found in the subsurface of the Sellafield nuclear licensed site, UK. The first programme, funded by the UK National Nuclear Laboratory (NNL), assessed the electrokinetic generation of iron-rich barriers at metre + scale in simulated Sellafield materials, while the second programme, funded under the current UK TRANSCEND consortium project, examined electrokinetic iron-barrier formation at smaller (<1 m) scale, but in real site materials. Both programmes indicate that iron-rich barriers can be conveniently and electrokinetically grown in different geometries over reasonable timescales (months) in realistic site subsurface materials (sands), in electrolytes similar to natural waters found in the environment. Voltage requirements are low (<1 V cm−1) with energy and consumables costs of no more than single-digit or tens of US dollars at the metre-plus scale. Further work is needed however to assess the longevity of the iron precipitates forming the subsurface barrier, and to explore barrier generation at the geometries and scales required for (site specific) field application.

652-662
Purkis, Jamie M.
17c76efb-2aa2-429e-92b3-5a21de7b02a5
Burrell, Frances
17557794-ae6b-4c71-9d9b-3fed6ebdbf49
Brydie, James R.
7d380208-ce69-4b39-a8c0-0dd55abeffd8
Graham, James
ba426094-6e0d-4ecf-a1e5-4a4e0a4f62fd
Hopkinson, Laurence
af67f81a-f8b9-4d90-aca9-069466822905
Cundy, Andrew B.
994fdc96-2dce-40f4-b74b-dc638286eb08
Purkis, Jamie M.
17c76efb-2aa2-429e-92b3-5a21de7b02a5
Burrell, Frances
17557794-ae6b-4c71-9d9b-3fed6ebdbf49
Brydie, James R.
7d380208-ce69-4b39-a8c0-0dd55abeffd8
Graham, James
ba426094-6e0d-4ecf-a1e5-4a4e0a4f62fd
Hopkinson, Laurence
af67f81a-f8b9-4d90-aca9-069466822905
Cundy, Andrew B.
994fdc96-2dce-40f4-b74b-dc638286eb08

Purkis, Jamie M., Burrell, Frances, Brydie, James R., Graham, James, Hopkinson, Laurence and Cundy, Andrew B. (2023) Electrokinetic generation of iron-rich barriers in soils: realising the potential for nuclear site management and decommissioning. Environmental Science: Advances, 2 (4), 652-662. (doi:10.1039/d2va00308b).

Record type: Article

Abstract

Following earlier field-scale pilot work on nuclear site materials in the late 2000s, there has recently been renewed research and industry interest in the application of electrokinetic technologies for nuclear site management and remediation in the UK. One relatively novel application of electrokinetics is the use of sacrificial steel electrodes (coupled with an in situ generated pH-Eh gradient in the treated material) to precipitate sub-surface iron-rich barriers for groundwater and/or leachate containment, which could be used to grout or contain contaminated fluids in the sub-surface on working nuclear sites or sites undergoing decommissioning. Here, we report previously unpublished data from two work programmes exploring the higher Technology Readiness Level (TRL) application of this electrokinetic iron-barrier approach to materials typical of those found in the subsurface of the Sellafield nuclear licensed site, UK. The first programme, funded by the UK National Nuclear Laboratory (NNL), assessed the electrokinetic generation of iron-rich barriers at metre + scale in simulated Sellafield materials, while the second programme, funded under the current UK TRANSCEND consortium project, examined electrokinetic iron-barrier formation at smaller (<1 m) scale, but in real site materials. Both programmes indicate that iron-rich barriers can be conveniently and electrokinetically grown in different geometries over reasonable timescales (months) in realistic site subsurface materials (sands), in electrolytes similar to natural waters found in the environment. Voltage requirements are low (<1 V cm−1) with energy and consumables costs of no more than single-digit or tens of US dollars at the metre-plus scale. Further work is needed however to assess the longevity of the iron precipitates forming the subsurface barrier, and to explore barrier generation at the geometries and scales required for (site specific) field application.

Text
Accepted manuscript
Available under License Creative Commons Attribution.
Download (13MB)
Text
Supporting information
Available under License Creative Commons Attribution.
Download (153kB)

More information

Accepted/In Press date: 28 February 2023
Published date: 6 March 2023
Additional Information: Funding Information: The authors thank the NDA, NNL and predecessors as well as authors for kindly providing access to many reports described here. The authors also thank GAU-Radioanalytical at the University of Southampton for experimental support. Part of this work has been funded through the TRANSCEND (TRANsformative SCience and Engineering for Nuclear Decommissioning) consortium from the UK's Engineering and Physical Sciences Research Council, EPSRC (reference EP/S01019X/1). We also acknowledge support from the National Nuclear User Facility EXACT (Next Generation Accelerated Characterisation Technologies), via EPSRC grant EP/T011548/1. We thank two anonymous reviewers for comments that improved the overall discussion of the data presented and its wider implications. Publisher Copyright: © 2023 RSC.

Identifiers

Local EPrints ID: 476313
URI: http://eprints.soton.ac.uk/id/eprint/476313
DOI: doi:10.1039/d2va00308b
PURE UUID: b83590fe-d1bb-4343-9e21-f5626b19c504
ORCID for Jamie M. Purkis: ORCID iD orcid.org/0000-0002-6387-1220
ORCID for Frances Burrell: ORCID iD orcid.org/0000-0002-6671-6680
ORCID for James Graham: ORCID iD orcid.org/0000-0001-5217-3104
ORCID for Andrew B. Cundy: ORCID iD orcid.org/0000-0003-4368-2569

Catalogue record

Date deposited: 19 Apr 2023 16:36
Last modified: 30 Jul 2024 02:01

Export record

Altmetrics

Contributors

Author: Jamie M. Purkis ORCID iD
Author: Frances Burrell ORCID iD
Author: James R. Brydie
Author: James Graham ORCID iD
Author: Laurence Hopkinson
Author: Andrew B. Cundy ORCID iD

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×