Coherent topological defect dynamics and collective modes in superconductors and electronic crystals

TL;DR

This paper explores how laser pulses can control and observe the dynamics of phase transitions, topological defects, and collective modes in superconductors and charge-density wave systems with femtosecond precision.

Contribution

It provides experimental insights into the real-time evolution of order parameters and topological defects during phase transitions, highlighting measurable coherent defect dynamics.

Findings

Observation of order parameter trajectories during phase transitions

Detection of coherent oscillations and defect-related modes

Evidence of defect creation, emission, and mixing with bosonic modes

Abstract

The control of condensed matter systems out of equilibrium by laser pulses allows us to investigate the system trajectories through symmetry-breaking phase transitions. Thus the evolution of both collective modes and single particle excitations can be followed through diverse phase transitions with femtosecond resolution. Here we present experimental observations of the order parameter trajectory in the normal-superconductor transition and charge-density wave ordering transitions. Of particular interest is the coherent evolution of topological defects forming during the transition via the Kibble-Zurek mechanism, which appears to be measurable in optical pump probe experiments. Experiments on CDW systems reveal some new phenomena, such as coherent oscillations of the order parameter, the creation and emission of dispersive amplitudon modes upon the annihilation of topological defects, and mixing with weakly coupled finite-frequency (massive) bosons.