Frustration-induced emergent Hilbert space fragmentation

Although most quantum systems thermalize locally on short timescales independent of initial conditions, recent developments have shown this is not always the case. Lattice geometry and quantum mechanics can conspire to produce constrained quantum dynamics and associated glassy behavior, a phenomenon that falls outside the rubric of the eigenstate thermalization hypothesis. Constraints fragment the many-body Hilbert space due to which some states remain insulated from others and the system fails to attain thermal equilibrium. Such fragmentation is a hallmark of geometrically frustrated magnets with low-energy icelike manifolds exhibiting a broad range of relaxation times for different initial states. Focusing on the highly frustrated kagome lattice, we demonstrate these phenomena in the Balents-Fisher-Girvin Hamiltonian (easy-axis regime), and a three-coloring model (easy-plane regime), both with constrained Hilbert spaces. We study their level statistics and relaxation dynamics to develop a coherent picture of fragmentation in various limits of the XXZ model on the kagome lattice.

Automated summary

This study explores how quantum systems, under the influence of lattice geometry and quantum mechanics, can exhibit constrained quantum dynamics and glassy behavior that deviates from the eigenstate thermalization hypothesis. Experimental demonstrations on the highly frustrated kagome lattice confirm the existence of constrained Hilbert spaces and fragmentation in relaxation dynamics.