Instabilities of heavy magnons in an anisotropic magnet

The search for new elementary particles is one of the most basic pursuits in physics, spanning from subatomic physics to quantum materials. Magnons are the ubiquitous elementary quasiparticle to describe the excitations of fully-ordered magnetic systems. But other possibilities exist, including fractional and multipolar excitations. Here, we demonstrate that strong quantum interactions exist between three flavors of elementary quasiparticles in the uniaxial spin-one magnet FeI2. Using neutron scattering in an applied magnetic field, we observe spontaneous decay between conventional and heavy magnons and the recombination of these quasiparticles into a super-heavy bound-state. Akin to other contemporary problems in quantum materials, the microscopic origin for unusual physics in FeI2 is the quasi-flat nature of excitation bands and the presence of Kitaev anisotropic magnetic exchange interactions. Magnons are elementary quasiparticles describing collective excitations of magnetic materials, however more complex quasiparticles can arise from attractive interactions between magnons. Here the authors report several types of magnetic excitations in a spin-1 magnet FeI2 and uncover new magnon decay paths.

Automated summary

The search for new elementary particles is a fundamental pursuit in physics, and magnons are the elementary quasiparticles describing excitations in magnetic systems. In this study, researchers demonstrate strong quantum interactions between different flavors of elementary quasiparticles in the magnet FeI2. Using neutron scattering, they observe spontaneous decay and recombination of conventional and heavy magnons, indicating the formation of a super-heavy bound-state. This work sheds light on the unusual physics in FeI2, which is attributed to the quasi-flat nature of excitation bands and the presence of Kitaev anisotropic magnetic exchange interactions.