High Frequency Acoustic Microscopy for the Determination of Porosity and Young's Modulus in High Burnup Uranium Dioxide Nuclear Fuel

During irradiation UO 2 nuclear fuel experiences the development of a non-uniform distribution of porosity which contributes to establish varying mechanical properties along the radius of the pellet. Radial variations of both porosity and elastic properties in high burnup UO 2 pellet can be investig...

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Bibliographic Details
Published in:IEEE transactions on nuclear science 2016-06, Vol.63 (3), p.1520-1525
Main Authors: Marchetti, Mara, Laux, Didier, Cappia, Fabiola, Laurie, M., Van Uffelen, P., Rondinella, V. V., Wiss, T., Despaux, G.
Format: Article
Language:English
Subjects:
Acoustic measurements
Acoustics
Electronics
Engineering Sciences
Fuels
Microscopy
Nuclear fuels
nuclear power
piezoelectric devices
Pumps
Scanning electron microscopy
Uranium
Vickers microhardness
Young's modulus
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Summary:During irradiation UO 2 nuclear fuel experiences the development of a non-uniform distribution of porosity which contributes to establish varying mechanical properties along the radius of the pellet. Radial variations of both porosity and elastic properties in high burnup UO 2 pellet can be investigated via high frequency acoustic microscopy. For this purpose ultrasound waves are generated by a piezoelectric transducer and focused on the sample, after having travelled through a coupling liquid. The elastic properties of the material are related to the velocity of the generated Rayleigh surface wave (V_R). A UO 2 pellet with a burnup of 67 GWd/tU was characterized using the acoustic microscope installed in the hot cells of the JRC-ITU at a 90 MHz frequency, with methanol as coupling liquid. V_R was measured at different radial positions. A good agreement was found, when comparing the porosity values obtained via acoustic microscopy with those determined using SEM image analysis, especially in the areas close to the centre. In addition, Young's modulus was calculated and its radial profile was correlated to the corresponding burnup profile and to the hardness radial profile data obtained by Vickers micro-indentation.
ISSN:0018-9499
1558-1578
DOI:10.1109/TNS.2016.2552241