Spin filtering on demand via localized states in an atomic-scale resonant tunneling magnetic tunnel junction

Bazarnik, Maciej; Schlenhoff, Anika

Research article (journal) | Peer reviewed

Abstract

Spin filtering and its back-action spin-transfer torque (STT) are key ingredients of the latest spintronic devices based on magnetic tunnel junctions (MTJs). Resonant tunneling (RT), implemented by design or occurring as parasitic effects, is known to crucially affect macroscopic device performance, but direct experimental access to its individual microscopic processes has remained difficult. Here, we apply the RT scheme from MTJs to spin-polarized scanning tunneling microscopy (SP-STM) for ultimate miniaturization obtained by addressing distinct sites on individual nanomagnets. Combined with energy selectivity, our experimental model setup enables us to study the spin filtering capabilities of RT through an individual spin-split vacuum resonance state and of the corresponding STT exerted on the nanomagnet. We find that the sign and magnitude of the STT follow the effective spin-polarization of the resonance state, which, as we show, can be tailored on demand either by adjusting the applied bias or the current injection point on the nanostructure. We anticipate that our atomic-scale RT-MTJ approach and the discovery of a versatile tunable spin filter at the smallest scale will prove invaluable for studying and designing next-generation MTJs, potentially based on recently discovered 2D van-der-Waals magnets or altermagnets.

Details about the publication

JournalACS Nano
Volume20
Page range16636null
StatusPublished
Release year2026
Language in which the publication is writtenEnglish
Keywordsresonant tunneling; magnetic tunnel junction (MTJ); spin-transfer torque; quantum well; spin filter; nanomagnets; spin-polarized scanning tunneling microscopy (SP-STM)

Authors from the University of Münster

Schlenhoff, Anika