Litcius/Paper detail

Quench dynamics and scaling laws in topological nodal loop semimetals

Karin Sim, R. Chitra, Paolo Molignini

2022Physical review. B./Physical review. B21 citationsDOI

Abstract

We employ quench dynamics as an effective tool to probe different universality classes of topological phase transitions. Specifically, we study a model encompassing both Dirac-like and nodal loop criticalities. Examining the Kibble-Zurek scaling of topological defect density, we discover that the scaling exponent is reduced in the presence of extended nodal loop gap closures. For a quench through a multicritical point, we also unveil a path-dependent crossover between two sets of critical exponents. Bloch state tomography finally reveals additional differences in the defect trajectories for sudden quenches. While the Dirac transition permits a static trajectory under specific initial conditions, we find that the underlying nodal loop leads to complex time-dependent trajectories in general. In the presence of a nodal loop, we generically find a mismatch between the momentum modes where topological defects are generated and where dynamical quantum phase transitions occur. We also find notable exceptions where this correspondence breaks down completely.

Topics & Concepts

PhysicsScalingLoop (graph theory)Universality (dynamical systems)Topology (electrical circuits)ExponentCritical exponentPhase transitionRenormalization groupStatistical physicsQuantum mechanicsGeometryMathematicsLinguisticsPhilosophyCombinatoricsTopological Materials and PhenomenaQuantum many-body systemsAdvanced Condensed Matter Physics