Abstract
Grain boundaries in Sr-doped LaMnO3±δ thin films have been shown to strongly influence the electronic and oxygen mass transport properties, being able to profoundly modify the nature of the material. The unique behavior of the grain boundaries can be correlated with substantial modifications of the cation concentration at the interfaces, which can be tuned by changing the overall cationic ratio in the films. In this work, we study the electronic properties of La0.8Sr0.2Mn1−yO3±δ thin films with variable Mn content. The influence of the cationic composition on the grain boundary and grain bulk electronic properties is elucidated by studying the manganese valence state evolution using spectroscopy techniques and by confronting the electronic properties of epitaxial and polycrystalline films. Substantial differences in the electronic conduction mechanism are found in the presence of grain boundaries and depending on the manganese content. Moreover, the unique defect chemistry of the nanomaterial is elucidated by measuring the electrical resistance of the thin films as a function of oxygen partial pressure, disclosing the importance of the cationic local non-stoichiometry on the thin film behavior.
Highlights
In this work, we delve into the electronic conduction mechanism of La0.8Sr0.2Mn1−yO3±δ (LSMy) thin films by studying, first, the impact of the different Mn/(La+Sr) ratios on the bulk behavior by spectroscopy techniques and, second, the grain boundaries (GBs) properties in polycrystalline samples by confronting them with epitaxial LSMy with variable Mn content
We recently showed that the GBs in LSM thin films are dominated by an unusual local modification of chemical composition, which involves both the oxygen and the cations
We delve into the electronic conduction mechanism of La0.8Sr0.2Mn1−yO3±δ (LSMy) thin films by studying, first, the impact of the different Mn/(La+Sr) ratios on the bulk behavior by spectroscopy techniques and, second, the GB properties in polycrystalline samples by confronting them with epitaxial LSMy with variable Mn content
Summary
We delve into the electronic conduction mechanism of La0.8Sr0.2Mn1−yO3±δ (LSMy) thin films by studying, first, the impact of the different Mn/(La+Sr) ratios on the bulk behavior by spectroscopy techniques and, second, the GB properties in polycrystalline samples by confronting them with epitaxial LSMy with variable Mn content.
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