Microbeam analysis of irradiated nuclear fuel

Walker, C.T.; Stephan, Bremier; Pöml, P.; Papaioannou, D.; Bottomley, D.

doi:10.1088/1757-899x/32/1/012028

Cited by 9 publications

(8 citation statements)

References 29 publications

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“…European Commission -Joint Research Centre, United States Quantitative x-ray microanalysis is a valuable tool for a wide range of nuclear applications. Typical examples for applications in the field of actinide materials are the analysis of fresh or spent nuclear fuel (post irradiation examination -PIE), the quantification of Pu or Am in materials used in radioisotope thermoelectric generators (RTGs) for space applications (see latest Mars rover Perseverance), or the analysis of materials formed during severe nuclear accidents like Three Mile Island, Chernobyl, and Fukushima [1][2][3].…”

Section: Philipp Pömlmentioning

confidence: 99%

Unresolved challenges in the microanalysis of actinides and nuclear materials

Pöml

2021

Microsc Microanal

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Section: Philipp Pömlmentioning

confidence: 99%

Unresolved challenges in the microanalysis of actinides and nuclear materials

Pöml

2021

Microsc Microanal

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“…Perhaps the most important nondestructive micro-analytical method that is used to improve the safety and performance of nuclear fuels with the potential of reducing high-level waste is electron probe microanalysis (EPMA) (Walker, 1999; Brémier et al, 2003, 2016; Lamontagne et al, 2007; Walker et al, 2012; Bottomley et al, 2014; Capriotti et al, 2014; Moy et al, 2014; Wiss et al, 2017; Gerczak et al, 2018; Llovet et al, 2020). EPMA is a fast and reliable tool usually applied to earth and material sciences, yet encounters several technical obstacles in nuclear fuel analysis.…”

Section: Introductionmentioning

confidence: 99%

“…These facilities are globally rare, while research and development on nuclear fuels is strictly regulated by (inter)national policies. Second, microprobe counting detectors and other sensitive parts in the column are exposed to high β- and γ-irradiation from the samples, which demands special and costly shielding (Walker, 1999; Lamontagne et al, 2007; Walker et al, 2012). Third, well-polished surfaces are crucial for the quality of quantitative analysis using EPMA, yet all of the common sample preparation steps such as embedding, grinding, polishing, and controlling the polishing status under a microscope have to be carried out in glove boxes (Walker, 1999; Lamontagne et al, 2007; Wright et al, 2018), but these “simple” steps are not necessarily available all in one glove box.…”

Section: Introductionmentioning

confidence: 99%

Improved Protocol for the Quantification of Actinides (Th, U, Np, Pu, Am, and Cm) Using Electron Probe Microanalysis

et al. 2021

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“…This results in greater production of fission products, and also in greater transmutation of those species due to neutron capture. In addition, elemental and isotopic compositions can change significantly within a few hundred micrometers of the edge of an individual fuel pellet due to the skin effect, in which epithermal neutrons are strongly captured by 238 U, resulting in copious production of Pu [5][6][7][8] . This in turn results in changes in the fission product distribution at the pellet edge because fission products of 239 Pu have a different elemental and isotopic distribution than those of 235 U.…”

mentioning

confidence: 99%

Simultaneous isotopic analysis of fission product Sr, Mo, and Ru in spent nuclear fuel particles by resonance ionization mass spectrometry

Savina

Isselhardt

Shulaker

et al. 2023

Sci Rep

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Fission product Sr, Mo, and Ru isotopes in six 10-μm particles of spent fuel from a pressurized water reactor were analyzed by resonance ionization mass spectrometry (RIMS) and evaluated for utility in nuclear material characterization. Previous measurements on these same samples showed widely varying U, Pu, and Am isotopic compositions owing to the samples’ differing irradiation environments within the reactor. This is also seen in Mo and Ru isotopes, which have the added complication of exsolution from the UO2 fuel matrix. This variability is a hindrance to interpreting data from a collection of particles with incomplete provenance since it is not always possible to assign particles to the same batch of fuel based on isotopic analyses alone. In contrast, the measured 90Sr/88Sr ratios were indistinguishable across all samples. Strontium isotopic analysis can therefore be used to connect samples with otherwise disparate isotopic compositions, allowing them to be grouped appropriately for interpretation. Strontium isotopic analysis also provides a robust chronometer for determining the time since fuel irradiation. Because of the very high sensitivity of RIMS, only a small fraction of material in each of the 10 μm samples was consumed, leaving the vast majority still available for other analyses.

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Microbeam analysis of irradiated nuclear fuel

Cited by 9 publications

References 29 publications

Unresolved challenges in the microanalysis of actinides and nuclear materials

Unresolved challenges in the microanalysis of actinides and nuclear materials

Improved Protocol for the Quantification of Actinides (Th, U, Np, Pu, Am, and Cm) Using Electron Probe Microanalysis

Simultaneous isotopic analysis of fission product Sr, Mo, and Ru in spent nuclear fuel particles by resonance ionization mass spectrometry

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