Your search keyword '"Sharrad, C. A."' showing total 3 results

1. Accessible Statistical Regression, Extrapolation and First-Principles Modelling of Nuclear Data for Spent Nuclear Fuel Composition and Decay Heat Calculations in Short-Term Storage and Recycling

Author

George K, Sharrad C, Adams S, and Holdsworth A

Subjects

Nuclear fuel cycle, Elemental composition, Nuclear engineering, Extrapolation, Environmental science, Nuclear data, Regression analysis, Decay heat, acoustics, Spent nuclear fuel, Term (time)

Abstract

Computational methods are essential to support and advance nuclear technologies due to the hazards of handling and analysing highly radioactive materials such as spent nuclear fuel (SNF). However, many such methods, including those thatcan predict SNF compositions and decay heat parameters, require expensive, proprietary software, alongside significant programming experience and computational power for utilisation, severely limiting availability of data and hampering research throughput. Although some datasets are available, many are incomplete or only cover certain fuel systems for older reactor types. Research investigating new methods for SNF recycling, for example, requires compositional and decay heat data for fuel systems not covered by extant data, though analogous source data may be available. With this in mind, we have developed a simple, accessible, and flexible method for extrapolation of isotopic, elemental, and decayheat compositions for SNF at discharge and following decay storage before recycling, based on an extant dataset. This semi-empirical method uses physical and mathematical first principles and can be performed using software accessible to all researchers. This provides outputs accurate to within 1% of reference values interpolated within the range of available data for isotopic compositions, with sensible extrapolations at higher burnups beyond those reported, withoverall elemental outputs accurate to within 0.1%of expected totals. In this publication, we present the developmental methodology, some sample data, the present limitations, and options for future development and expansion of functionality.

Published

2020

2. Actinide, lanthanide, and fission product speciation and electrochemistry in ionic melts

Author

Bhatt, A. I., Kinoshita, H., Koster, A. L., May, I., Sharrad, C., Steele, H. M., Vladimir Volkovich, Fox, O. D., Jones, C. J., Lewin, B. G., Charnock, J. M., and Hennig, C.

Subjects

SPECTROSCOPY, LIQUIDS, CHEMISTRY, CHLORIDE, COMPLEXES, MOLTEN-SALTS

Abstract

We report the results of recent research that we have undertaken to increase our understanding of key actinide and fission product speciation in a range of ionic melts. These results will be used to develop novel electrochemical methods of separation of uranium and plutonium from irradiated nuclear fuel. Our studies in high temperature alkali metal melts (including LiCl and the eutectics LiCl-KCl and CsCI-NaCl) have focussed on in-situ speciation of U, Tc and Ru using both Electronic Absorption Spectroscopy (EAS) and X-ray Absorption Spectroscopy (XAS). The XAS studies have included Extended X-Ray Absorption Fine Structure (EXAFS) and X-Ray Absorption Near Edge Structure (XANES) measurements. We report what could be unusual uranium speciation in high temperature melts and evaluate the likelihood of Ru or Tc volatilisation during plant operation. Our studies in lower temperature melts, commonly known as ionic liquids, have focussed on salts containing tertiary alkyl group 15 cations and the bis(trifluoromethylsulphonyl)imide anion, melts which we know to have exceptionally wide electrochemical windows. We report Ln, Th, U and Np speciation (XAS, EAS and vibrational spectroscopy) and electrochemistry in these melts.

3. Gadolinium speciation with tetradentate, N-donor extractants for minor actinide/lanthanide separation: An XRD, mass spectrometry and EPR study

Author

Daniel Whittaker, Sharrad, C. A., and Sproules, S.