Topological phase transitions and Berry-phase hysteresis in exchange-coupled nanomagnets

TL;DR

This paper investigates topological phase transitions and introduces Berry-phase hysteresis in exchange-coupled cobalt nanoparticles, combining experimental, theoretical, and simulation approaches to reveal new magnetic phenomena relevant for spintronics.

Contribution

It presents the first experimental observation and theoretical explanation of Berry-phase hysteresis in nanomagnets, expanding understanding of topological effects in magnetic nanostructures.

Findings

Identification of topological phase transitions in cobalt nanoparticles

Discovery of Berry-phase hysteresis in the topological Hall effect

Micromagnetic simulations linking chiral domains to the Hall effect

Abstract

Topological phase in magnetic materials yields a quantized contribution to the Hall effect known as the topological Hall effect, which is often caused by skyrmions, with each skyrmion creating a magnetic flux quantum h/e. The control and understanding of topological properties in nanostructured materials is the subject of immense interest for both fundamental science and technological applications, especially in spintronics. In this work, the electron-transport properties and spin structure of exchange-coupled cobalt nanoparticles with an average particle size of 13.7 nm are studied experimentally and theoretically. Magnetic and Hall-effect measurements identify topological phase transitions in the exchange-coupled cobalt nanoparticles and were used to discover a qualitatively new type of hysteresis in the topological Hall effect namely, Berry-phase hysteresis. Micromagnetic simulations reveal the origin of the topological Hall effect namely, the chiral domains, with domain-wall chirality quantified by an integer skyrmion number. These spin structures are different from the skyrmions formed due to Dzyaloshinskii Moriya interactions in B20 crystals and multilayered thin films, and caused by cooperative magnetization reversal in the exchange-coupled cobalt nanoparticles. An analytical model is developed to explain the underlying physics of Berry-phase hysteresis, which is strikingly different from the iconic magnetic hysteresis and constitutes one aspect of 21st-century reshaping of our view on nature at the borderline of physics, chemistry, mathematics, and materials science.