Prediction and characterisation of radiation damage in fluorapatite

Jay, Eleanor E.; Fossati, Paul; Rushton, Michael; Grimes, Robin W.

doi:10.1039/c4ta01707b

Cited by 23 publications

(13 citation statements)

References 45 publications

(58 reference statements)

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“…Similar effect was predicted by Jay et.al. from molecular dynamics study of fluorapatite by alpha radiation cascade [43] . As predicted by their study a large proportion of PO 4 3− group are remained intact however within the core of the damaged region, small amount of PO x units is found to get stabilized in chain like P−O−P structure.…”

Section: Resultsmentioning

confidence: 83%

Exploring the Thermodynamic Behavior and the Effect of Temperature and Electron Radiation on the Structure of Fluorapatite Compounds

et al. 2021

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Fluorapatite compounds of calcium and strontium; (Ca10(PO4)6F2 and Sr10(PO4)6F2), are being explored as alternative to borosilicate glass matrix for nuclear waste immobilization. This study is aimed at investigating the thermodynamic behavior of these compounds as well as the effect of temperature and electron radiation on their crystal lattice. Heat capacity and enthalpy increments of these compounds were measured using calorimetric technique. Thermal expansion up to 1073 K was measured by High Temperature X‐ray Diffraction (HT‐XRD). Electron beam radiation induced polymeric phosphate linkage formation in the structure was evidenced by vibrational spectroscopy (FTIR and Raman). Combined XRD, IR and Raman study revealed that Ca10(PO4)6F2 is more resistant towards structural damage upon electron beam irradiation as compared to Sr10(PO4)6F2.

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Section: Resultsmentioning

confidence: 83%

Exploring the Thermodynamic Behavior and the Effect of Temperature and Electron Radiation on the Structure of Fluorapatite Compounds

et al. 2021

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“…Thus, the grains are considered to be amorphous when all the diffraction spots disappear after Kr ion irradiations. However, because of the recrystallization along exactly the same orientation, it is likely that there is a glass-like material where the aperiodic rotations of phosphate tetrahedra are sufficient to distort the atoms and cause the disappearance of diffraction spots after Kr ion damage, while the fluorine channels of the fluorapatite structure remained almost intact, as discovered by the Molecular Dynamics (MD) simulation 36 . The undamaged fluorine channels 36 after Kr ion irradiation may provide a framework for the recovery of the structure in the same orientation by the irradiation of alpha-particles.…”

Section: In Situ He + Ion Irradiationsmentioning

confidence: 99%

“…However, more recent work reported much higher values, ~5,000 for alpha-recoil in natural zircon 46 and 10,000 for 239 Pu in a PuCoGa 5 superconductor 47 , using Nuclear Magnetic Resonance (NMR) and Extended X-Ray Absorption Fine Structure (EXAFS), respectively. The MD simulation gives a final ~2,000 displaced atoms per 5 keV recoil in apatite 36 . In order to compare 70 keV Th damage in natural apatite and 1 MeV Kr ion irradiations, SRIM simulation is used in both cases for consistency.…”

Section: Quantification Of the Dpa In Natural Apatite From mentioning

confidence: 99%

In situ TEM observation of alpha-particle induced annealing of radiation damage in Durango apatite

Shen

Zhou

et al. 2017

Sci Rep

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A major issue in thermochronology and U-Th-Pb dating is the effect of radiation damage, created by α-recoils from α-decay events, on the diffusion of radiogenic elements (e.g., He and Pb) in host mineral. Up until now, thermal events have been considered as the only source of energy for the recovery of radiation-damage. However, irradiation, such as from the α-particle of the α-decay event, can itself induce damage recovery. Quantification of radiation-induced recovery caused by α-particles during α-decay events has not been possible, as the recovery process at the atomic-scale has been difficult to observe. Here we present details of the dynamics of the amorphous-to-crystalline transition process during α-particle irradiations using in situ transmission electron microscopy (TEM) and consecutive ion-irradiations: 1 MeV Kr2+ (simulating α-recoil damage), followed by 400 keV He+ (simulating α-particle annealing). Upon the He+ irradiation, partial recrystallization of the original, fully-amorphous Durango apatite was clearly evident and quantified based on the gradual appearance of new crystalline domains in TEM images and new diffraction maxima in selected area electron diffraction patterns. Thus, α-particle induced annealing occurs and must be considered in models of α-decay event damage and its effect on the diffusion of radiogenic elements in geochronology and thermochronology.

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“…Ca 10 (PO 4 ) 6 F 2 (FAP) nanocrystals have been playing important role in the development of suitable luminescent materials for ionizing and non-ionizing radiation dosimetry, and protection as well [1][2][3][4]. In last few decades, UV radiation measurements and protection attracted high attention considering the harmful effects on ecosystems as a consequence of degradation of ozone layer, but also the biological effects of high energy photons of the UV radiation on eyes and skin [5,6].…”

Section: Introductionmentioning

confidence: 99%

Effects of Ag⁺ Ion Doping on UV Radiation Absorption and Luminescence Profiles of Fluorapatite Nanomaterials Obtained by Neutralization Method

et al. 2019

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In the present study we have analyzed effects of Ag + ions doping on energetic profiles of nanophosphors materials based on fluorapatite crystal system. The UV radiation absorption and luminescence properties of monophase fluorapatite (FAP) and Ag + doped fluorapatite (AgFAP) nanomaterials obtained by neutralization method were investigated using the photoluminescence spectrophotometry. The excitation-emission profiles of nanomaterials were analyzed statistically by MCR-ALS method and number of fluorophores was extracted. FAP lattice absorbed light at 350 nm in the UVA part of spectrum, and with increasing concentration of Ag + ions new absorption maximum appeared at 270 nm in the UVC part. Fluorescence of FAP nanoparticles was in violet region of visible part of the spectrum, with a red shift to the green region when Ag + was doped in lattice. MCR-ALS analyses of fluorescence spectra confirm formation of two maxima, at 484 and 505 nm, as a consequence of Ag + ions doping in FAP lattice at Ca1 (4f) sites. The results of quantum chemical calculations showed that an Ag + ion is stronger bonded to the binding site 1 (−1352.6 kcal/mol) than to the binding site 2 (−1249.0 kcal/mol). Considering that AgFAP1 nanopowder absorbs photons over all part of UV radiation spectrum, this material might be used as potential radiation protective nanomaterial.

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Prediction and characterisation of radiation damage in fluorapatite

Cited by 23 publications

References 45 publications

Exploring the Thermodynamic Behavior and the Effect of Temperature and Electron Radiation on the Structure of Fluorapatite Compounds

Exploring the Thermodynamic Behavior and the Effect of Temperature and Electron Radiation on the Structure of Fluorapatite Compounds

In situ TEM observation of alpha-particle induced annealing of radiation damage in Durango apatite

Effects of Ag⁺ Ion Doping on UV Radiation Absorption and Luminescence Profiles of Fluorapatite Nanomaterials Obtained by Neutralization Method

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Prediction and characterisation of radiation damage in fluorapatite

Cited by 23 publications

References 45 publications

Exploring the Thermodynamic Behavior and the Effect of Temperature and Electron Radiation on the Structure of Fluorapatite Compounds

Exploring the Thermodynamic Behavior and the Effect of Temperature and Electron Radiation on the Structure of Fluorapatite Compounds

In situ TEM observation of alpha-particle induced annealing of radiation damage in Durango apatite

Effects of Ag+ Ion Doping on UV Radiation Absorption and Luminescence Profiles of Fluorapatite Nanomaterials Obtained by Neutralization Method

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Effects of Ag⁺ Ion Doping on UV Radiation Absorption and Luminescence Profiles of Fluorapatite Nanomaterials Obtained by Neutralization Method