Spin Elliptically Restricted Multilayered at Sub-Nanometer Regime

Oral-In-person  · Withdrawn

Abstract

In recent years, there has been an increased focus on the symmetry particular attitude, particularly in relation to its analysis of quantum metrics and its application in the context of R-space quasiparticles (QPs). In a similar vein, quantum magnetism has exhibited sub-nanometer limits with microscopic quantum models in the gyromagnetic. However, these limits remain elusive due to the prevalence of experimental standard quantum limits, particularly when systems manifest magnetoelectronic bias. Moreover, the demonstration of field-free topological magnetism in heteroarchitectures presented here is based on the aforementioned concept and achieved through the implementation of stacking-engineered magnonics. Our proprietary framework elucidates the manner in which transitions into non- and orthogonally twist-tuned interlayer coupling give rise to emergent magnetic phenomena when Rashba and DMI interactions cooperate. It is imperative to acknowledge the observation of stable swirls, which are characterized by their robust topological protection. This phenomenon is driven by the dynamics of canted phases of spin, which amplify the Berry curvature. Thus, this platform facilitates orbital-resolved spin control without the need for external fields, thereby paving the way for the development of 2D spintronic memory.

Presenters

  • Brandon Pedroza

    • Autonomous University of the State of Hidalgo

Authors

  • Brandon Pedroza

    • Autonomous University of the State of Hidalgo
  • Ariadna Sánchez-Castillo