Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-29T10:18:09.001Z Has data issue: false hasContentIssue false

Development of Surface Marker System for the Observation of Microstructural Changes in Nuclear Graphite using Micro X-ray Tomography

Published online by Cambridge University Press:  23 March 2012

Rosemary A. Holmes
Affiliation:
Nuclear Graphite research Group, University of Manchester, Sackville St, Manchester, M13 9PL, UK.
Abbie N. Jones
Affiliation:
Nuclear Graphite research Group, University of Manchester, Sackville St, Manchester, M13 9PL, UK.
Lorraine McDermott
Affiliation:
Nuclear Graphite research Group, University of Manchester, Sackville St, Manchester, M13 9PL, UK.
Barry Marsden
Affiliation:
Nuclear Graphite research Group, University of Manchester, Sackville St, Manchester, M13 9PL, UK.
Get access

Abstract

Current energy demands and future energy needs are a growing industry which at present attracts a large amount of research and investment of which nuclear energy is an integral part. Eight new nuclear stations are proposed to be developed in the UK over the next ten years to meet this demand. In order for nuclear energy to sustain growth and development, nuclear decommissioning of first and second generation power stations needs to be addressed in the U.K. and worldwide. Presently the UK has 36 graphite moderated reactors as a result of the UK military and civil programs, which over the next twenty years will close. This will result in ∼99’000 tonnes of irradiated graphite waste for which no current national decommissioning strategy exists. The main issues associated with this waste are the large volume and activation products associated. By far the greatest inventory is from 3H and 14C. An EU Euroatom FP7 Program; CARBOWASTE was established in 2008 with the aim of developing treatment and disposal options for graphite.

This research is based within CARBOWASTE, the main objectives are to understand the mechanisms involved in the production, location and removal of radioisotopes from nuclear graphite. Computed X-ray Tomography (CT) will be used in order to quantify the initial porosity in conjunction with thermal treatment (ex situ) in order to eventually identify the location of 14C within the matrix of irradiated graphite, through the preferential chemically controlled oxidation of graphite. Unirradiated Pile Grade A graphite samples have been laser and manually marked in order align the samples prior to and post thermal treatment to determine the degree of porosity changes and weight loss under a range of thermal oxidation parameters.

Type
Articles
Copyright
Copyright © Materials Research Society 2012

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1. NDA, Final Waste Issues Group Report. 2007.Google Scholar
2. NDA, Radioactive Wastes in the UK: A Summary of the 2001 Inventory. 2002.Google Scholar
3. Podruzhina, T., Graphite as radioactive waste corrosion behaviour under final repository conditions and thermal treatment., in FZJ Report 2004: Jülich.Google Scholar
4. Bradtec Decon Technologies, L., Graphite Decommissioning Options for Graphite Treatment, Recycling, or Disposal, including a discussion of Safety-Related Issues, E.P.R.I. (EPRI). Editor. 2006.Google Scholar
5. IAEA. Technical Committee Meeting in Nuclear Graphite Waste Management. 1999. Manchester: IAEA Austria.Google Scholar
6. Wickham, A.J. On the Formation and Behaviour of 14C in Irradiated Graphite: A Preliminary Review. in INGSM. 2011. Eastborne, UK.Google Scholar