Reto Pfenninger scite author profile

We use first-principles calculations to investigate the stability of bi-axially strained Pnma perovskite CaMnO3 towards the formation of oxygen vacancies. Our motivation is provided by promising indications that novel material properties can be engineered by application of strain through coherent heteroepitaxy in thin films. While it is usually assumed that such epitaxial strain is accommodated primarily by changes in intrinsic lattice constants, point defect formation is also a likely strain relaxation mechanism. This is particularly true at the large strain magnitudes (>4%) which first-principles calculations often suggest are required to induce new functionalities. We find a strong dependence of oxygen vacancy defect formation energy on strain, with tensile strain lowering the formation energy consistent with the increasing molar volume with increasing oxygen deficiency. In addition, we find that strain differentiates the formation energy for different lattice sites, suggesting its use as a route to engineering vacancy ordering in epitaxial thin films.

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A low ride on processing temperature for fast lithium conduction in garnet solid-state battery films

Pfenninger

et al. 2019

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Glass‐Type Polyamorphism in Li‐Garnet Thin Film Solid State Battery Conductors

Garbayo

Struzik

Bowman

et al. 2018

Advanced Energy Materials

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Ceramic Li7La3Zr2O12 garnet materials are promising candidates for the electrolytes in solid state batteries due to their high conductivity and structural stability. In this paper, the existence of “polyamorphism” leading to various glass‐type phases for Li‐garnet structure besides the known crystalline ceramic ones is demonstrated. A maximum in Li‐conductivity exists depending on a frozen thermodynamic glass state, as exemplified for thin film processing, for which the local near range order and bonding unit arrangement differ. Through processing temperature change, the crystallization and evolution through various amorphous and biphasic amorphous/crystalline phase states can be followed for constant Li‐total concentration up to fully crystalline nanostructures. These findings reveal that glass‐type thin film Li‐garnet conductors exist for which polyamorphism can be used to tune the Li‐conductivity being potential new solid state electrolyte phases to avoid Li‐dendrite formation (no grain boundaries) for future microbatteries and large‐scale solid state batteries.

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Reto Pfenninger

Strain-controlled oxygen vacancy formation and ordering in CaMnO3

A low ride on processing temperature for fast lithium conduction in garnet solid-state battery films

Glass‐Type Polyamorphism in Li‐Garnet Thin Film Solid State Battery Conductors

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