The current-induced spin-torques provide an efficient means of manipulating magnetization,
introducing the way for next generation spintronic devices. During the past decades, studies …

A synthetic antiferromagnet, composed of two ferromagnetic layers separated by a non-
magnetic layer, possesses two uniform precession resonance modes: in-phase acoustic …

In ferromagnetic materials, the rich dynamics of magnetic domain walls (DWs) under a
magnetic field or current has been successfully described using the well-known q-φ …

The current-driven domain wall motion along two exchange-coupled ferromagnetic layers
with perpendicular anisotropy is studied by means of micromagnetic simulations and …

The next-generation logic and memory devices using magnetic skyrmions as spintronic
information carriers are frequently studied, thanks to their remarkable magnetic stability …

Synthetic antiferromagnetically coupled (SAF) multilayers provide different physics of
stabilizing skyrmions while eliminating the topological Hall effect (THE), enabling efficient …

Nanoscale skyrmions are spin-based quasiparticles that are promising for nonvolatile logic
applications. However, the presence of the skyrmion Hall effect (SkHE) in ferromagnetic …

A domain wall based spin torque nano-oscillator is a potential device for microwave
generation because of its tunability of frequency, operation at room temperature, and …

Spin–orbit torque (SOT)-induced reversal of a ferromagnet in a magnetic tunnel junction
(MTJ) is promising for next-generation novel magnetic memory and spin-logic devices …

The stability of a long-periodic homogeneous spin-spiral configuration in an inverse
tetragonal Heusler compound, Mn 2 PtSn, is studied with the help of density functional …