Hybridization-induced interface states in a topological insulator-magnetic metal heterostructure

TL;DR

This study models and simulates a topological insulator-magnetic metal heterostructure, revealing a new interface state formed by hybridization that could explain large spin-transfer torques observed experimentally.

Contribution

It introduces the concept of a 'descendent state' formed through hybridization, providing new insights into interface states affecting spin-transfer torque in TI-FM heterostructures.

Findings

Original Dirac cone is destroyed by hybridization.

A new 'descendent state' forms near the Fermi level.

The 'descendent state' inherits properties of the original Dirac state.

Abstract

Recent experiments demonstrating large spin-transfer torques in topological insulator (TI)-ferromagnetic metal (FM) bilayers have generated a great deal of excitement due to their potential applications in spintronics. The source of the observed spin-transfer torque, however, remains unclear. This is because the large charge transfer from the FM to TI layer would prevent the Dirac cone at the interface from being anywhere near the Fermi level to contribute to the observed spin-transfer torque. Moreover, there is yet little understanding of the impact on the Dirac cone at the interface from the metallic bands overlapping in energy and momentum, where strong hybridization could take place. Here, we build a simple microscopic model and perform first-principles-based simulations for such a TI-FM heterostructure, considering the strong hybridization and charge transfer effects. We find that the original Dirac cone is destroyed by the hybridization as expected. Instead, we find a new interface state which we dub 'descendent state' to form near the Fermi level due to the strong hybridization with the FM states at the same momentum. Such a `descendent state' carries a sizable weight of the original Dirac interface state, and thus inherits the localization at the interface and the same Rashba-type spin-momentum locking. We propose that the `descendent state' may be an important source of the experimentally observed large spin-transfer torque in the TI-FM heterostructure.