Measuring the dispersion relations of spin wave bands using time-of-flight spectroscopy

TL;DR

This paper introduces a novel all-inductive time-of-flight spectroscopy method to measure the dispersion relations of multiple spin wave branches in magnetic thin films, even when they coexist in the same frequency range.

Contribution

The authors develop a generic technique that separates and measures multiple spin wave branches using time-gating and phase analysis, overcoming limitations of existing methods.

Findings

Successfully measured dispersion relations of multiple spin wave branches.

Demonstrated the method's effectiveness in complex multi-branch scenarios.

Provided a new approach for detailed spin wave band structure analysis.

Abstract

We develop a generic all-inductive procedure to measure the band structure of spin waves in a magnetic thin stripe. In contrast to existing techniques, our method works even if several spin wave branches coexist in the investigated frequency interval, provided that the branches possess sufficiently different group velocities. We first measure the microwave scattering matrix of a network composed of distant antennas inductively coupled to the spin wave bath of the magnetic film. After a mathematical transformation to the time-domain to get the transmission impulse response, the different spin wave branches are viewed as wavepackets that reach successively the receiving antenna after different travel times. In analogy with time-of flight spectroscopy, the wavepackets are then separated by time-gating. The time-gated responses are used to recalculate the contribution of each spin wave branch to the frequency domain scattering matrix. The dispersion relation of each branch stems from the absolute phase of the time-gated transmission parameter. The spin wave wavevector can be determined unambiguously if the results for several propagation distances are combined, so as to get the dispersion relations.