Development of Melilite‐Type Oxide Ion Conductors

Zhou, Lijia; Xu, Jungu; Allix, Mathieu; Kuang, Xiaojun

doi:10.1002/tcr.202000069

Cited by 30 publications

(38 citation statements)

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“…On the other hand, trivalent RE cations contribute toward the stabilization of the oxygen interstitials by forming ionic bonding with the excess oxide ions, 132 which requires large RE cations. More information on the development of melilite-type oxide ion conductors can be found in a review recently published by Zhou et al 133…”

Section: Res Based Mellite Structurementioning

confidence: 99%

Rare earth elements based oxide ion conductors

Kuang

Sun

2021

Inorg. Chem. Front.

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Section: Res Based Mellite Structurementioning

confidence: 99%

Rare earth elements based oxide ion conductors

Kuang

Sun

2021

Inorg. Chem. Front.

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“…Understanding the mechanisms on the oxide anionic defect stabilization and oxide ion mobility is imperative in order to improve the oxide ion conductivity and design new oxide ion conductors with better performance. Recently, the materials based on tetrahedral units, for example, apatites, melilites, , and scheelites, , have attracted more and more attention on developing oxide ion conducting electrolytes owing to their high ionic conductivity. ,, The deformation and rotation flexibility of tetrahedral units facilitate the stabilization and transportation of oxygen interstitial or vacancy defects even within the low symmetric structures, ,, in contrast with the traditional fluorite and perovskite-type electrolytes. , …”

Section: Introductionmentioning

confidence: 99%

Experimental and Theoretical Solid-State ²⁹Si NMR Studies on Defect Structures in La_9.33+x(SiO₄)₆O_2+1.5x Apatite Oxide Ion Conductors

et al. 2021

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Oxide ion conductors can be used as electrolytes in solid oxide fuel cells, a promising energy-conversion technology. Local structures around the defects in oxide ion conductors are key for understanding the defect stabilization and migration mechanisms. As the defect contents are generally low, it is rather difficult to characterize the defect structure and therefore elucidate how oxide ions migrate. Solid-state nuclear magnetic resonance (NMR) spectroscopy is a powerful technique for probing the local structures. However, the interpretation of NMR signals mainly based on the empirical knowledge could lead to unprecise local structures. There is still controversy regarding the defect structures in the apatite-type interstitial oxide ion conductors containing isolated tetrahedral units. Here, we combine the experimental solid-state 29 Si NMR spectroscopy with theoretical density functional theory calculations to investigate the defect structures in La 9.33+x (SiO 4 ) 6 O 2+1.5x apatites. The results indicate that the 29 Si resonance signals on the high field side of the main peak corresponding to the Si atoms in the bulk structure are related to La vacancies and there is no steady-state SiO 5 in the defect structures. This finding provides new atomic-level understanding to the stabilization and migration of interstitial oxide ions in silicate apatites, which could guide the design and discovery of new solid oxide fuel cell electrolyte materials.

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“…In La 1+x AE 1−x Ga 3 O 7+x/2 (AE = Ca 2+ , Sr 2+ , or Ba 2+ ), interstitial oxide ions (O int ) are incorporated into the framework close to the centers of the pentagonal rings by tuning the La 3+ /AE 2+ ratio (x). 13 This creates GaO 5 trigonal bipyramidal units locally by coordination of O int to gallium ions within the tetrahedral layer, which is stabilized by a substantial bonding contribution from the two adjacent La 3+ /Sr 2+ cations. 14,15 At elevated temperatures, these interstitial oxide ions act as charge carriers, primarily by diffusion within the Ga−O framework layer.…”

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“…Its structure (general formula: A 2 B 3 O 7 ) consists of a two-dimensional framework of corner-sharing 3- and 4-connected BO 4 tetrahedra forming distorted pentagonal channels perpendicular to the stacking axis, which alternates with a layer of A cations in an 8-fold coordination by oxide ions. In La 1+ x AE 1– x Ga 3 O 7+ x /2 ( AE = Ca 2+ , Sr 2+ , or Ba 2+ ), interstitial oxide ions (O int ) are incorporated into the framework close to the centers of the pentagonal rings by tuning the La 3+ / AE 2+ ratio ( x ) . This creates GaO 5 trigonal bipyramidal units locally by coordination of O int to gallium ions within the tetrahedral layer, which is stabilized by a substantial bonding contribution from the two adjacent La 3+ /Sr 2+ cations. , At elevated temperatures, these interstitial oxide ions act as charge carriers, primarily by diffusion within the Ga–O framework layer. , Consequently, the ionic conductivity (σ) depends directly on the concentration of interstitial oxide ( x ) in the framework.…”

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La₂Ga₃O_7.5: A Metastable Ternary Melilite with a Super-Excess of Interstitial Oxide Ions Synthesized by Direct Crystallization of the Melt

et al. 2020

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The La1+x AE 1–x Ga3O7+x/2 melilite family (AE = Ca, Sr, and Ba and 0 ≤ x ≤ 0.64) demonstrates remarkable oxide ion conductivity due to the ability of its layered tetrahedral [Ga3O7+x/2] network to accommodate and transport interstitial oxide ions (Oint). Compositions of x > 0.65 with very high Oint concentrations (referred to here as “super-excess” compositions) have the potential to support correspondingly high ionic conductivities but have never before been accessed due to the limitations of conventional solid-state ceramic synthesis. Here, we report that fully substituted La2Ga3O7.5 (x = 1) melilite ceramics can be synthesized by direct crystallization of an under-cooled melt, demonstrating that super-excess compositions are accessible under suitable nonequilibrium reaction conditions. La2Ga3O7.5 is stable up to 830 °C and exhibits an ionic conductivity of 0.01 S·cm–1 at 800 °C, 3 orders of magnitude higher than the corresponding x = 0 end-member LaSrGa3O7 and close to the range exhibited by the current best-in-class La1.54Sr0.46Ga3O7.23 (0.1 S·cm–1). It crystallizes in an orthorhombic √2a × √2a × 2c expansion of the parent melilite cell in the space group Ima2 with full long-range ordering of Oint into chains within the [Ga3O7.5] layers. The emergence of this chain-like (1D) ordering within the 2D melilite framework, which appears to be an incipient feature of previously reported partially ordered melilites, is explained in terms of the underlying hexagonal topology of the structure. These results will enable the exploration of extended compositional ranges for the development of new solid oxide ion electrolytes with high concentrations of interstitial oxide charge carriers.

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Development of Melilite‐Type Oxide Ion Conductors

Cited by 30 publications

References 55 publications

Rare earth elements based oxide ion conductors

Rare earth elements based oxide ion conductors

Experimental and Theoretical Solid-State ²⁹Si NMR Studies on Defect Structures in La_9.33+x(SiO₄)₆O_2+1.5x Apatite Oxide Ion Conductors

La₂Ga₃O_7.5: A Metastable Ternary Melilite with a Super-Excess of Interstitial Oxide Ions Synthesized by Direct Crystallization of the Melt

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Development of Melilite‐Type Oxide Ion Conductors

Cited by 30 publications

References 55 publications

Rare earth elements based oxide ion conductors

Rare earth elements based oxide ion conductors

Experimental and Theoretical Solid-State 29Si NMR Studies on Defect Structures in La9.33+x(SiO4)6O2+1.5x Apatite Oxide Ion Conductors

La2Ga3O7.5: A Metastable Ternary Melilite with a Super-Excess of Interstitial Oxide Ions Synthesized by Direct Crystallization of the Melt

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Experimental and Theoretical Solid-State ²⁹Si NMR Studies on Defect Structures in La_9.33+x(SiO₄)₆O_2+1.5x Apatite Oxide Ion Conductors

La₂Ga₃O_7.5: A Metastable Ternary Melilite with a Super-Excess of Interstitial Oxide Ions Synthesized by Direct Crystallization of the Melt