The Quantification of Radiation Damage in Orthophosphates Using Confocal μ-Luminescence Spectroscopy of Nd3+

Lenz, Christoph; Thorogood, Gordon J.; Aughterson, Robert D.; Ionescu, Mihail; Gregg, Daniel J.; Davis, Joel; Lumpkin, Gregory R.

doi:10.3389/fchem.2019.00013

Cited by 21 publications

(20 citation statements)

References 76 publications

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“…), and thus are similar to Raman spectroscopy, a practical probe for the characterization of local structural disorder (Lenz et al. ). In analogy to Raman spectra, Nd 3+ luminescence bands likewise broaden with increasing degree of amorphization (see again Fig.…”

Section: Resultsmentioning

confidence: 98%

Partial amorphization of experimentally shocked plagioclase: A spectroscopic study

Pittarello

Fritz²,

Roszjar

et al. 2020

Meteorit & Planetary Scien

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Shock amorphization of plagioclase, from partial to complete, has been used to evaluate the degree of shock in meteorites. Important information on the shock amplitude can be derived from the measurement of the refractive index in plagioclase, either from mineral separates or in petrographic thin sections. However, this technique is timeconsuming, and associated sample preparations are considered destructive and are not always possible for precious and rare meteorite samples. In addition, plagioclase amorphization is commonly inhomogeneous at the sample scale and a statistically meaningful number of grains must be considered. Here, we apply several nondestructive spectroscopic techniques, such as Raman spectroscopy, photoluminescence, and cathodoluminescence, to plagioclase experimentally shocked at 28 GPa, and thus in the transition regime between crystalline plagioclase and fully amorphous material. Most of the plagioclase was transformed into diaplectic glass at 28 GPa, yet some grains exhibit heterogeneously distributed crystalline domains. This confirms that intrinsic and extrinsic factors lead to local variations in the intensity of the shock pressure within individual plagioclase crystals of homogeneous composition. The amorphization of plagioclase can qualitatively (and potentially also quantitatively) be investigated by spectroscopic techniques, highlighting such local variations in the shock efficiency.

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Section: Resultsmentioning

confidence: 98%

Partial amorphization of experimentally shocked plagioclase: A spectroscopic study

Pittarello

Fritz²,

Roszjar

et al. 2020

Meteorit & Planetary Scien

Self Cite

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“…[27] However, based on photoluminescence spectra and TEM results, the damage accumulation in xenotime (YPO4) samples were observed to be heterogenous in the irradiated surface layer and that the amorphous fraction was observed to decrease unto a depth of 5 µm. [27] The heterogenous damage layer observed in the YPO4 ceramics were proposed to be a result of the epitaxial annealing occurring at the crystalline-amorphous interface. [27] To the best of our knowledge, the impact of light-ions such as He + on the structure of pristine/amorphous xenotime has not been studied.…”

Section: Introductionmentioning

confidence: 99%

“…[26] Lenz et al in a recent study implanted xenotime-type (YPO4) ceramics sequentially with Auions of different energies (35,22,14,7 MeV) and fluences (1.6 × 10 13 -6.5 × 10 13 ions/cm 2 ) and determined the amount of amorphous fraction using photoluminescence spectroscopy. [27] Quadruple high energy Auions were chosen in that study in order to create an homogenous thick damage layer of ~5µm. [27] However, based on photoluminescence spectra and TEM results, the damage accumulation in xenotime (YPO4) samples were observed to be heterogenous in the irradiated surface layer and that the amorphous fraction was observed to decrease unto a depth of 5 µm.…”

Section: Introductionmentioning

confidence: 99%

“…[27] Quadruple high energy Auions were chosen in that study in order to create an homogenous thick damage layer of ~5µm. [27] However, based on photoluminescence spectra and TEM results, the damage accumulation in xenotime (YPO4) samples were observed to be heterogenous in the irradiated surface layer and that the amorphous fraction was observed to decrease unto a depth of 5 µm. [27] The heterogenous damage layer observed in the YPO4 ceramics were proposed to be a result of the epitaxial annealing occurring at the crystalline-amorphous interface.…”

Section: Introductionmentioning

confidence: 99%

“…[27] The heterogenous damage layer observed in the YPO4 ceramics were proposed to be a result of the epitaxial annealing occurring at the crystalline-amorphous interface. [27] To the best of our knowledge, the impact of light-ions such as He + on the structure of pristine/amorphous xenotime has not been studied. In this regard, the present study aims to address the question whether α-particles could induce a healing effect on the structure of amorphized…”

Section: Introductionmentioning

confidence: 99%

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An in-situ electron microscopy study of dual ion-beam irradiated xenotime-type ErPO4

Rafiuddin

Seydoux‐Guillaume²,

Deschanels³

et al. 2020

Journal of Nuclear Materials

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Rare-earth phosphates adopting the xenotime (REPO4; RE = Tb-Lu & Y, Sc) structure are proposed as a potential matrix for the confinement of minor actinides. Minor actinides (e.g., Np, Am, Cm) undergo a radioactive decay process in which high-energy recoil atom (70-100 keV) and energetic alpha particles (4.5-5.8 MeV) are produced. In this study, the impact of these energetic decay products on the structure of xenotime-type ErPO4 has been investigated via high energy dual ion-beam irradiation of ErPO4 ceramics. Au 2+ (1.5 MeV) and He + (160 keV) ions were used to simulate the effects of recoil atom and α-particles, respectively. Multiple experiments were carried out in which the Au 2+ and He + ions with varying ion-fluences (ions/cm 2) and ion-flux (ions/cm 2 /s) were implanted sequentially (Au 2+ followed by He + irradiation) and simultaneously (Au 2+ + He + irradiation) into ErPO4 ceramics. Sequential ion-irradiation experiments have shown that the xenotime structure was amorphized by Au 2+ ions at a relatively lower ion-fluence (5 × 10 13 ions/cm 2) in comparison to the monazite structure. Upon irradiation of the amorphous ErPO4 with He + ions, recrystallization of the amorphous xenotime due to α-particles was not observed. However, simultaneous ion-irradiation experiments on ErPO4 showed that the amorphization of the xenotime structure was prevented upon deposition of higher amounts of electronic energy (Eelectronic) in the lamella. Likewise monazite samples, the α-healing mechanism was also experimentally demonstrated in synthetic xenotime samples.

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Benefits of using multiple Raman laser wavelengths for characterizing defects in a UO₂ matrix

Karcher

Mohun

Olds

et al. 2022

J Raman Spectroscopy

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Raman spectroscopy is one of the most useful techniques for studying the structure of UO 2 and changes due to specific defects caused by doping, changes in stoichiometry, irradiation, or heating under oxidizing conditions. In this paper, we illustrate several aspects of the application of Raman techniques to the study of UO 2 , including the use of wavelength-dependent excitation (455, 532, and 785 nm) to assess the effects of doping (Nd, Th, and Zr), ion irradiation, and in situ heating and oxidation (UO 2 to U 3 O 8 ). Additionally, we show examples of how correlative microscopy is possible using electron backscatter diffraction combined with Raman maps of specific vibration bands or of laser-induced luminescence generated by rare-earth dopants in the matrix.For each of these applications, we suggest optimal excitation wavelengths that vary depending on the desired data. Blue (455 nm) excitation tends to promote oxidation even at low powers, but because Raman spectra change little with doping, irradiation-induced changes are easier to observe. Green (532 nm) excitation is optimal for observing electron-phonon resonance effects in UO 2 and offers a good compromise for high-temperature oxidation experiments, delivering high-quality spectra for both UO 2 and U 3 O 8 . Infrared (785 nm) excitation is best for observing "defect" bands associated with doping in UO 2 , as changes with irradiation are small. Raman spectroscopy is particularly suited for studying the stability of UO 2 towards oxidation in the presence of dopants simulating fission products, where electron-phonon resonant effects, dopant ion luminescence, and mapping can be used together to investigate structural rearrangement as a function of temperature. These techniques can offer insight into microstructural changes in UO 2 fuels at higher burnups envisioned in future reactors.

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The Quantification of Radiation Damage in Orthophosphates Using Confocal μ-Luminescence Spectroscopy of Nd3+

Cited by 21 publications

References 76 publications

Partial amorphization of experimentally shocked plagioclase: A spectroscopic study

Partial amorphization of experimentally shocked plagioclase: A spectroscopic study

An in-situ electron microscopy study of dual ion-beam irradiated xenotime-type ErPO4

Benefits of using multiple Raman laser wavelengths for characterizing defects in a UO₂ matrix

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The Quantification of Radiation Damage in Orthophosphates Using Confocal μ-Luminescence Spectroscopy of Nd3+

Cited by 21 publications

References 76 publications

Partial amorphization of experimentally shocked plagioclase: A spectroscopic study

Partial amorphization of experimentally shocked plagioclase: A spectroscopic study

An in-situ electron microscopy study of dual ion-beam irradiated xenotime-type ErPO4

Benefits of using multiple Raman laser wavelengths for characterizing defects in a UO2 matrix

Contact Info

Product

Resources

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Benefits of using multiple Raman laser wavelengths for characterizing defects in a UO₂ matrix