Structural, optical tuning, and mechanical behavior of zirconia toughened alumina through europium substitutions

Ponnilavan, V.; Kannan, S.

doi:10.1002/jbm.b.34210

Cited by 13 publications

(4 citation statements)

References 54 publications

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“…In particular, the stabilization capacity of Y 3+ (1.019 Å) in ZrO 2 has been documented extensively in previous reports that ensured the stabilization of tetragonal ZrO 2 polymorph with Y 3+ content in the range of 3–8 mol‐%, while its cubic polymorph is retained beyond 8 mol‐% , . In a similar manner, the effects of rare earth elements on the stabilization capacity of ZrO 2 polymorphs have been documented , , . 10 mol‐% of individual substitution of different rare earths such as Yb 3+ (0.985 Å), Dy 3+ (1.027 Å), Tb 3+ (1.040 Å), Gd 3+ (1.053 Å), Eu 3+ (1.066 Å) and Nd 3+ (1.109 Å) ensured t ‐ZrO 2 stabilization until 1500 °C.…”

Section: Discussionmentioning

confidence: 63%

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca₃(PO₄)₂ and t‐ZrO₂ Crystal Structures

2020

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An in situ aqueous precipitation with the aid of Gd3+ as a stabilizer has been used to attain a series of β‐Ca3(PO4)2/t‐ZrO2 composites. Analytical characterization techniques were used to investigate the formation of desired composite during progressive heat treatments. The transformation of calcium deficient apatite to β‐Ca3(PO4)2, which usually occurs at ≈ 780 °C for pure systems, is delayed to beyond 1100 °C, depending upon the concentration of Gd3+/Zr4+ used in the synthesis. Gd3+ prefers to accommodate at the lattice sites of both β‐Ca3(PO4)2 and t‐ZrO2. Gd3+ ensures limited occupancy at the Ca2+(1), Ca2+(2), and Ca2+(3) of β‐Ca3(PO4)2 while t‐ZrO2 consumes the excess Gd3+. Phase pure β‐Ca3(PO4)2/t‐ZrO2 composite mixtures devoid of any secondary phase alongside enhanced structural stability were accomplished at 1500 °C. The micrographs of the composite specimen revealed good sintering behaviour, and the Youngs modulus and hardness data determined from indentation displayed significant variations depending on the phase content of the individual components in the composite system.

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Section: Discussionmentioning

confidence: 63%

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca₃(PO₄)₂ and t‐ZrO₂ Crystal Structures

2020

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“…Nevertheless, the gradual water mediated phase transformation t‐ZrO 2 (P42/nmc) → m‐ZrO 2 (P21/c) leads to implant failure and restricts the long term applications of ZrO 2 in vivo. Zirconia toughened alumina (ZTA) proposed as an alternative to t ‐ZrO 2 also encounter with similar shortcomings, especially the ZrO 2 component of ZTA experience t ‐ → m ‐ZrO 2 transformation during in vivo implantation 1,2 . Among the available alternatives, zircon (ZrSiO 4 ), a combination ZrO 2 and SiO 2 that possesses the prominent features of high refractive index, hardness, low thermal expansion coefficient and high melting point is considered a better choice 3 .…”

Section: Introductionmentioning

confidence: 99%

Synthesis, characterization, mechanical and magnetic characteristics of Gd³⁺/PO₄³⁻ substituted zircon for application in hard tissue replacements

Alam,

Vijayalakshmi

et al. 2023

J Biomed Mater Res

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The study reports on the use of sol–gel technique to yield zircon type [Zr(1–0.1–x) GdxTi0.1] [(SiO4)1–x(PO4)x] solid solution. Titanium has been used as a mineralizer to trigger zircon formation while equimolar concentrations of Gd3+ and PO43− were added to determine their accommodation limits in the zircon structure. The crystallization of t‐ZrO2 as a dominant phase alongside the crystallization of m‐ZrO2 and zircon were detected at 1200°C while their further annealing revealed the formation of zircon as a major phase at 1300°C. Heat treatment at 1400°C revealed the formation of zircon‐type solid solution [Zr(1–0.1‐x)GdxTi0.1][(SiO4)1−x(PO4)x] comprising the accommodation of 10 mol.% of Gd3+/PO43− at the zircon lattice. Beyond 10 mol.% of Gd3+/PO43−, the crystallization of GdPO4 as a secondary phase is noticed. Structural analysis revealed the expansion of zircon lattice due to the simultaneous occupancy of Gd3+/PO43− for the corresponding Zr4+/SiO44− sites. The mechanical strength of single‐phase zircon solid solution was higher in comparison to that of multiphase materials, namely in the presence of GdPO4 formed as a secondary phase in samples with added equimolar Gd3+/PO43− contents beyond 10 mol.%. Nevertheless, the paramagnetic behavior of the samples demonstrated a steady surge as a function of enhanced Gd3+ content.

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“…28,[50][51][52] This indicates that the Eu ions remain located in the core during the shelling, since the presence of Eu ions in the shell would suppress the ZrO2 defect emission (either by preventing the defect to form or by energy transfer to Eu). [53][54][55] Therefore, the overall emission spectrum of the core/shells contains emission from Eu 3+ in the core and defect emission from the shells. This also explains the drastic increase in the lifetime of the core/shell particles, since the Eu 3+ ions are now in a perfect environment far from the outside.…”

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confidence: 99%

Epitaxial Core/Shell Nanocrystals of (Europium-Doped) zirconia and hafnia

Seno,

Reichholf,

Salutari

et al. 2024

Preprint

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A careful design of nanocrystal architecture can strongly enhance the nanocrystal function. So far, this strategy faced a synthetic bottleneck in the case of refractory oxides. Here, we demonstrate the epitaxial growth of hafnia shells onto zirconia cores, and pure zirconia shells onto europium doped zirconia cores. The core/shell structures are fully crystalline. Upon shelling, the optical properties of the europium dopant are dramatically improved (featuring a more uniform coordination and a longer photoluminescence lifetime), indicating the suppression of non-radiative pathways. These results launch the stable zirconium and hafnium oxide hosts as alternatives for the established NaYF4 systems.

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Structural, optical tuning, and mechanical behavior of zirconia toughened alumina through europium substitutions

Cited by 13 publications

References 54 publications

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca₃(PO₄)₂ and t‐ZrO₂ Crystal Structures

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca₃(PO₄)₂ and t‐ZrO₂ Crystal Structures

Synthesis, characterization, mechanical and magnetic characteristics of Gd³⁺/PO₄³⁻ substituted zircon for application in hard tissue replacements

Epitaxial Core/Shell Nanocrystals of (Europium-Doped) zirconia and hafnia

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Structural, optical tuning, and mechanical behavior of zirconia toughened alumina through europium substitutions

Cited by 13 publications

References 54 publications

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca3(PO4)2 and t‐ZrO2 Crystal Structures

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca3(PO4)2 and t‐ZrO2 Crystal Structures

Synthesis, characterization, mechanical and magnetic characteristics of Gd3+/PO43− substituted zircon for application in hard tissue replacements

Epitaxial Core/Shell Nanocrystals of (Europium-Doped) zirconia and hafnia

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Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca₃(PO₄)₂ and t‐ZrO₂ Crystal Structures

Combined Occupancy of Gadolinium at the Lattice Sites of β‐Ca₃(PO₄)₂ and t‐ZrO₂ Crystal Structures

Synthesis, characterization, mechanical and magnetic characteristics of Gd³⁺/PO₄³⁻ substituted zircon for application in hard tissue replacements