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Are insulating LiF barriers relevant for spin-polarized tunnelling applications? Insights from first-principles calculations

Publication at Faculty of Mathematics and Physics |
2016

Abstract

Structural, electronic and magnetic properties of Fe/LiF (0 0 1) interfaces and spin-polarized transport properties of Fe/LiF/Fe (001) heterostructures are studied by means of self-consistent atomistic first-principles calculations. Total energy calculations performed for various interfacial geometries show that the Fe/LiF (001) interface with Fe atoms located above anionic sites is the most stable.

F-Fe and Li-Fe substitutional intermixings at Fe/LiF (001) interfaces are not energetically favourable, but F accumulation in the interstitial void spaces at Fe/LiF (001) interfaces is possible. The magnetism of interfacial Fe atoms is robust.

The majority-spin ferromagnetic state conductances decay rapidly with respect to the barrier thickness, while the minority-spin ones have very large contributions at specific hot spots and play a major role in the transport properties. Depending on the interfacial geometry, tunnelling magnetoresistance ratios ranging from 460%-2400% are evidenced.

Interfacial interdiffusion can affect the transport properties. The exchange coupling between Fe electrodes through LiF barriers is negligible.