2015
DOI: 10.1039/c4cp05554c
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Strain effects on oxygen migration in perovskites

Abstract: Fast oxygen transport materials are necessary for a range of technologies, including efficient and cost-effective solid oxide fuel cells, gas separation membranes, oxygen sensors, chemical looping devices, and memristors. Strain is often proposed as a method to enhance the performance of oxygen transport materials, but the magnitude of its effect and its underlying mechanisms are not well-understood, particularly in the widely-used perovskite-structured oxygen conductors. This work reports on an ab initio pred… Show more

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Cited by 80 publications
(86 citation statements)
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“…Another effect that could contribute to the elongated shape of structural domains is migration anisotropy within LSMO. Lattice strains in perovskite oxides are known to affect the diffusion coefficient via a change of interatomic bond lengths2728, favouring oxygen migration perpendicular to the elongated unit cell29. Elongation of the out-of-plane lattice spacing in an oxygen-deficient LSMO film would thus favour horizontal oxygen vacancy migration.…”
Section: Resultsmentioning
confidence: 99%
“…Another effect that could contribute to the elongated shape of structural domains is migration anisotropy within LSMO. Lattice strains in perovskite oxides are known to affect the diffusion coefficient via a change of interatomic bond lengths2728, favouring oxygen migration perpendicular to the elongated unit cell29. Elongation of the out-of-plane lattice spacing in an oxygen-deficient LSMO film would thus favour horizontal oxygen vacancy migration.…”
Section: Resultsmentioning
confidence: 99%
“…The range of approximate estimated k * values for the different strain states were obtained using the estimate of 89 meV/(% strain) variation in the activation barrier for k *. This estimate was based on the maximum difference in the calculated activation barriers for O migration with strain for an array of perovskite materials 32 (additional details on how k * was approximated can be found Supplementary Note 3). It is important to note that the as-grown state was used as the reference for the calculations of k *; thus, the computed lattice response times are all relative to the initial, equilibrium as-grown state.…”
Section: Resultsmentioning
confidence: 99%
“…Oxygen vacancy mobility may also be enhanced by more facile reduction of B site cations since transfer of some electron density from oxygen makes it smaller and more able to pass through the A-A-B cation triangle [39,40]; in this sense migration enthalpies may scale with oxygen vacancy formation enthalpies. Tensile strain has also been calculated to decrease the migration barrier for oxygen hopping in perovskites [41]. The presence of cation vacancies and their induced disorder has additionally been suggested to increase the ionic mobility [42].…”
Section: Role Of Bulk Chemistrymentioning
confidence: 99%
“…Again epitaxial thin film model electrodes, such as deposited by PLD, are an asset in performing fundamental studies, as strain can be induced by the energetic growth process and/or by coherent lattice mismatch with the substrate or adjacent layers (accounting for thermal and chemical expansion). Beyond enhancements in oxide ion mobility [41] or incorporation kinetics that may be derived by stretching the lattice through which the ion passes, there is also a chemo-mechanical coupling in many systems, whereby the applied strain can lead to changes in point defect chemistry [93]. Both of these effects could, in principle, alter surface oxygen incorporation/excorporation energetics.…”
Section: Role Of Surface Chemistrymentioning
confidence: 99%