Litcius/Paper detail

A quantum critical Bose gas of magnons in the quasi-two-dimensional antiferromagnet YbCl3 under magnetic fields

Y. Matsumoto, Simon Schnierer, J. A. N. Bruin, Jürgen Nuß, Pascal Reiss, George Jackeli, Kentaro Kitagawa, H. Takagi

2024Nature Physics12 citationsDOIOpen Access PDF

Abstract

Abstract Bose–Einstein condensation (BEC) is a quantum phenomenon in which a macroscopic number of bosons occupy the lowest energy state and acquire coherence at low temperatures. In three-dimensional antiferromagnets, a magnetic-field-induced transition has been successfully described as a magnon BEC. For a strictly two-dimensional (2D) system, it is known that BEC cannot take place due to the presence of a finite density of states at zero energy. However, in a realistic quasi-2D magnet consisting of stacked magnetic layers, a small but finite interlayer coupling stabilizes marginal BEC but such that 2D physics is still expected to dominate. This 2D-limit BEC behaviour has been reported in a few materials but only at very high magnetic fields that are difficult to access. The honeycomb S = 1/2 Heisenberg antiferromagnet YbCl 3 exhibits a transition to a fully polarized state at a relatively low in-plane magnetic field. Here, we demonstrate the formation of a quantum critical 2D Bose gas at the transition field, which, with lowering the field, experiences a BEC marginally stabilized by an extremely small interlayer coupling. Our observations establish YbCl 3 , previously a Kitaev quantum spin liquid material, as a realization of a quantum critical BEC in the 2D limit.

Topics & Concepts

MagnonPhysicsAntiferromagnetismBose gasCondensed matter physicsQuantumMagnetic fieldQuantum mechanicsBose–Einstein condensateFerromagnetismAdvanced Condensed Matter PhysicsPhysics of Superconductivity and MagnetismQuantum, superfluid, helium dynamics