Litcius/Paper detail

Frustration-driven magnetic fluctuations as the origin of the low-temperature skyrmion phase in Co7Zn7Mn6

Victor Ukleev, Kosuke Karube, P. M. Derlet, Chennan Wang, H. Luetkens, Daisuke Morikawa, Akiko Kikkawa, Lucile Mangin-Thro, Andrew Wildes, Yuichi Yamasaki, Yuichi Yokoyama, Lili Yu, Cínthia Piamonteze, Nicolas Jaouen, Y. Tokunaga, H. M. Rønnow, T. Arima, Yoshinori Tokura, Y. Taguchi, J. S. White

2021npj Quantum Materials30 citationsDOIOpen Access PDF

Abstract

Abstract In chiral cubic helimagnets, phases of magnetic skyrmions—topologically protected spin whirls—are stabilized by thermal fluctuations over a narrow region directly below the magnetic ordering temperature T c . Due to often being touted for use in applications, there is a high demand to identify new ways to stabilize equilibrium skyrmion phases far below T c where they may display an enhanced robustness against external perturbation due to a larger magnetic order parameter. Here, from quantum beam experiments on the chiral magnet Co 7 Zn 7 Mn 6 , we unveil a direct correlation between the stability of its second skyrmion phase-stable far from T c , and a concomitant enhancement of an underlying magnetic fluctuation rate that is driven by geometric magnetic frustration. The influences of other leading skyrmion stability mechanisms, such as those derived from thermal fluctuations and low T cubic anisotropies, are shown to be weak in this system. We therefore advance the existence of a fundamental mechanism for stabilizing topological skyrmions in Co 7 Zn 7 Mn 6 chiral magnet that draws upon magnetic frustration as the key ingredient.

Topics & Concepts

SkyrmionFrustrationCondensed matter physicsThermal fluctuationsPhysicsMagnetQuantum fluctuationAnisotropyMagnetic fieldThermalQuantumQuantum mechanicsThermodynamicsMagnetic properties of thin filmsMagnetic and transport properties of perovskites and related materialsMagnetic Properties of Alloys