Real space observation of magnon interaction with driven space-time crystals

TL;DR

This paper demonstrates the creation and observation of room-temperature magnonic space-time crystals using microwave pumping and X-ray microscopy, revealing complex magnon interactions and ultra-short spin waves.

Contribution

It introduces the experimental realization of driven magnonic space-time crystals at room temperature and explores their unique band structure and magnon interactions.

Findings

Observation of a driven space-time crystal in a permalloy stripe

Formation of a magnonic band structure due to mode back folding

Generation of ultra-short spin waves down to 100 nm wavelength

Abstract

The concept of Space-Time Crystals (STC), i.e. translational symmetry breaking in time and space, was recently proposed and experimentally demonstrated for quantum systems. Here, we transfer this concept to magnons and experimentally demonstrate a driven STC at room temperature. The STC is realized by strong homogeneous micro-wave pumping of a micron-sized permalloy (Py) stripe and is directly imaged by Scanning Transmission X-ray Microscopy (STXM). For a fundamental understanding of the formation of the STC, micromagnetic simulations are carefully adapted to model the experimental findings. Beyond the mere generation of a STC, we observe the formation of a magnonic band structure due to back folding of modes at the STC's Brillouin zone boundaries. We show interactions of magnons with the STC that appear as lattice scattering. This results in the generation of ultra short spin waves down to 100 nm wavelength that cannot be described by classical dispersion relations for linear spin wave excitations. We expect that room temperature STCs will be a useful tool to investigate non-linear wave physics, as they can be easily generated and manipulated to control their spatial and temporal band structure.