Spin liquids in geometrically perfect triangular antiferromagnets
Yuesheng Li, Philipp Gegenwart, Alexander A Tsirlin
Abstract
The cradle of quantum spin liquids, triangular antiferromagnets show strong proclivity to magnetic order and require deliberate tuning to stabilize a spin-liquid state. In this brief review, we juxtapose recent theoretical developments that trace the parameter regime of the spin-liquid phase, with experimental results for Co-based and Yb-based triangular antiferromagnets. Unconventional spin dynamics arising from both ordered and disordered ground states are discussed, and the notion of a geometrically perfect triangular system is scrutinized to demonstrate non-trivial imperfections that may assist magnetic frustration in stabilizing dynamic spin states with peculiar excitations.
Topics & Concepts
Condensed matter physicsSpin (aerodynamics)PhysicsFrustrationOrder (exchange)QuantumQuantum fluctuationSpin waveQuantum spin liquidFerromagnetismQuantum mechanicsTRACE (psycholinguistics)Ground stateDynamics (music)First orderMagnetic structureAdvanced Condensed Matter PhysicsTopological Materials and PhenomenaPhysics of Superconductivity and Magnetism