Dissolution, Reactor, and Environmental Behavior of ZrO2-MgO Inert Fuel Matrix

Authors

Kenneth Czerwinski, University of Nevada, Las VegasFollow

Document Type

Annual Report

Publication Date

2006

First page number:

42

Last page number:

43

Abstract

This project examines inert fuels containing ZrO₂ and MgO as the inert matrix, with the relative amount of MgO varied from 30% to 70% in ZrO₂. Reactor physics calculations are used to examine suitable quantities of burnable poisons from the candidate elements Gd, Er, or Hf with reactor grade Pu providing the fissile component, with up to 10% of ²³⁹Pu. Ceramics are synthesized and characterized based on the reactor physics results. The solubility of the fuel ceramics, in reactor conditions, reprocessing conditions, and repository conditions, are investigated in a manner to provide thermodynamic data necessary for modeling.

The research objectives of this project are as follows:

• To examine the neutronic behavior of MgO-ZrO₂ inert fuels. Analysis of Gd, Er, and Hf for reactivity control ranging from 5-10% lanthanides. Analysis of reactor grade Pu as fissile component ranging from 5-10% Pu. Results will be used as parameters for fuel composition.
• To synthesize and characterize of MgO-ZrO₂ ceramics containing burnable poison and fissile composition. Synthesis is based on a precipitation method. Characterization of ceramics will include density, X-ray diffraction, surface area analysis, X-ray absorption fine structure spectroscopy, and chemical composition. Results will be applied to behavior in high temperature water, acid, and environmental conditions.
• To describe the chemical behavior of synthesized ceramics. Chemical thermodynamic and kinetic analysis will use equilibrium data, kinetic data, and surface area normalized dissolution. Different conditions will include reactor conditions (high temperature and high pressure water) and reprocessing conditions (nitric acid and elevated temperature). Environmental conditions will be near neutral solution conditions.
• To utilize project data in kinetic and thermodynamic modeling codes to evaluate the speciation of the elements in the ceramics under reactor, reprocessing, and repository conditions.

Keywords

Ceramics; Magnesium oxide; Mixed oxide fuels (Nuclear engineering); Nuclear chemistry; Nuclear fuels; Plutonium; Solid oxide fuel cells; Zirconium oxide

Controlled Subject

Ceramics; Mixed oxide fuels (Nuclear engineering); Nuclear chemistry

Disciplines

Ceramic Materials | Chemistry | Nuclear | Nuclear Engineering | Oil, Gas, and Energy | Physical Chemistry | Radiochemistry

File Format

pdf

File Size

207 KB

Language

English

Repository Citation

Czerwinski, K. (2006). Dissolution, Reactor, and Environmental Behavior of ZrO2-MgO Inert Fuel Matrix. 42-43.
Available at: https://digitalscholarship.unlv.edu/hrc_trp_fuels/66