Role of composition, bond covalency, and short-range order in the disordering of stannate pyrochlores by swift heavy ion irradiation

Tracy, Cameron L.; Shamblin, Jacob; Park, Sulgiye; Zhang, F.X.; Trautmann, C.; Lang, Maik; Ewing, Rodney C.

doi:10.1103/physrevb.94.064102

Cited by 61 publications

(66 citation statements)

References 68 publications

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“…Pyrochlore materials show clear compositional trends in radiation tolerance. Like the lanthanide sesquioxides, cation ionic radii are the primary determinant of these trends [28,[95][96][97][98]. For pyrochlore materials the ratio of the A-and B-site cation radii, r A /r B , governs radiation tolerance.…”

Section: Radiation Effects In Structurally-related Lanthanide Oxidesmentioning

confidence: 99%

“…This indicates that doping of CeO 2 with additional cations, particularly smaller transition metal elements, such as the fission frag-ments found in nuclear fuels and nuclear wastes, might reduce the radiation tolerance of this material. This doping, if sufficiently extensive, could make accessible irradiation-induced phase transformation pathways to amorphous phases, as well as short-range structural modifications resulting from local defect ordering [97,[100][101][102]. Thus, deviation from the ideal CeO 2 chemical composition due to the introduction of other atomic species appears likely to have a deleterious effect on radiation tolerance in this system.…”

Section: Radiation Effects In Structurally-related Lanthanide Oxidesmentioning

confidence: 99%

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Review of Swift Heavy Ion Irradiation Effects in CeO2

Cureton

Tracy

Lang

2021

QuBS

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Cerium dioxide (CeO2) exhibits complex behavior when irradiated with swift heavy ions. Modifications to this material originate from the production of atomic-scale defects, which accumulate and induce changes to the microstructure, chemistry, and material properties. As such, characterizing its radiation response requires a wide range of complementary characterization techniques to elucidate the defect formation and stability over multiple length scales, such as X-ray and neutron scattering, optical spectroscopy, and electron microscopy. In this article, recent experimental efforts are reviewed in order to holistically assess the current understanding and knowledge gaps regarding the underlying physical mechanisms that dictate the response of CeO2 and related materials to irradiation with swift heavy ions. The recent application of novel experimental techniques has provided additional insight into the structural and chemical behavior of irradiation-induced defects, from the local, atomic-scale arrangement to the long-range structure. However, future work must carefully account for the influence of experimental conditions, with respect to both sample properties (e.g., grain size and impurity content) and ion-beam parameters (e.g., ion mass and energy), to facilitate a more direct comparison of experimental results.

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Section: Radiation Effects In Structurally-related Lanthanide Oxidesmentioning

confidence: 99%

Section: Radiation Effects In Structurally-related Lanthanide Oxidesmentioning

confidence: 99%

Review of Swift Heavy Ion Irradiation Effects in CeO2

Cureton

Tracy

Lang

2021

QuBS

Self Cite

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“…The behavior of defects in pyrochlore is important for many of these applications. As such, multiple methods for introducing defects into pyrochlore have been investigated in the past, including radiation damage 18–21 , high pressure 22–24 , and chemical doping 25–27 . A thorough understanding of the pyrochlore crystal structure is necessary to assess the behavior of defects in the material, and how those atomic-level defects can influence bulk properties.…”

Section: Introductionmentioning

confidence: 99%

Strain engineered pyrochlore at high pressure

Rittman

Turner

Park

et al. 2017

Sci Rep

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Strain engineering is a promising method for next-generation materials processing techniques. Here, we use mechanical milling and annealing followed by compression in diamond anvil cell to tailor the intrinsic and extrinsic strain in pyrochlore, Dy2Ti2O7 and Dy2Zr2O7. Raman spectroscopy, X-ray pair distribution function analysis, and X-ray diffraction were used to characterize atomic order over short-, medium-, and long-range spatial scales, respectively, under ambient conditions. Raman spectroscopy and X-ray diffraction were further employed to interrogate the material in situ at high pressure. High-pressure behavior is found to depend on the species and concentration of defects in the sample at ambient conditions. Overall, we show that defects can be engineered to lower the phase transformation onset pressure by ~50% in the ordered pyrochlore Dy2Ti2O7, and lower the phase transformation completion pressure by ~20% in the disordered pyrochlore Dy2Zr2O7. These improvements are achieved without significantly sacrificing mechanical integrity, as characterized by bulk modulus.

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“…Likewise, Er 2 Zr 2 O 7 (r A /r B = 1.39) crystallizes in the defected fluorite structure and exhibits high radiation tolerance, while Er 2 Ti 2 O 7 (r A /r B = 1.66) crystallizes in the pyrochlore structure with poor radiation tolerance. A comprehensive study of the lanthanide stannate pyrochlores, Ln 2 Sn 2 O 7 (Ln = La to Lu and Y) confirmed this trend of increasing radiation tolerance with decreasing r A /r B [12,13]. A similar analysis of the oxygen positional parameter of the O 48f site, x, compared to that for the ideal pyrochlore structure (x = 0.3125) and the ideal (non-defective) fluorite structure (x = 0.375), leads to similar conclusions regarding radiation tolerance: those oxides which exhibit x values closer to the ideal fluorite value exhibit higher radiation tolerance than those with x values closer to the ideal pyrochlore structure [1,7].…”

Section: Introductionmentioning

confidence: 69%

Damage evolution of ion irradiated defected-fluorite La2Zr2O7 epitaxial thin films

et al. 2017

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Pyrochlore-structure oxides, A 2 B 2 O 7 , may exhibit remarkable radiation tolerance due to the ease with which they can accommodate disorder by transitioning to a defected fluorite structure. The mechanism of defect formation was explored by evaluating the radiation damage behavior of high quality epitaxial La 2 Zr 2 O 7 thin films with the defected fluorite structure, irradiated with 1 MeV Zr + at doses up to 10 displacements per atom (dpa). The level of film damage was evaluated as a function of dose by Rutherford backscattering spectrometry in the channeling geometry (RBS/c) and scanning transmission electron microscopy (STEM). At lower doses, the surface of the La 2 Zr 2 O 7 film amorphized, and the amorphous fraction as a function of dose fit well to a stimulated amorphization model. As the dose

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Role of composition, bond covalency, and short-range order in the disordering of stannate pyrochlores by swift heavy ion irradiation

Cited by 61 publications

References 68 publications

Review of Swift Heavy Ion Irradiation Effects in CeO2

Review of Swift Heavy Ion Irradiation Effects in CeO2

Strain engineered pyrochlore at high pressure

Damage evolution of ion irradiated defected-fluorite La2Zr2O7 epitaxial thin films

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