Theory of propagating spin wave spectroscopy using inductive antennas: conditions for unidirectional energy flow

TL;DR

This paper develops a formalism for propagating spin wave spectroscopy using inductive antennas, clarifies helicity mismatch effects, and demonstrates conditions for unidirectional energy flow and reconfigurable filters in spin wave devices.

Contribution

It introduces a method to analyze and optimize spin wave devices for unidirectional energy flow, focusing on helicity mismatch and dispersion relations, with practical applications in reconfigurable filters.

Findings

Helicity mismatch causes amplitude non-reciprocity in spin waves.

Line-shaped dispersion relations enable quasi-unidirectional spin wave emission.

Configuration near parallel wavevector and field allows reconfigurable frequency filtering.

Abstract

Many recent papers report on the interest of spin waves for applications. This paper revisits the propagating spin wave spectroscopy when using inductive transceivers connected to a network analyzer. The spin wave conduit can be made of a non-reciprocal material. The formalism offers a method to understand, design and optimize devices harnessing propagating spin waves, including when a unidirectional energy flow is desired. The concept of the mismatch of helicity between the spin wave and the magnetic field radiated by antennas is first clarified. Owing to the form of the susceptibility tensor reflecting the precession ellipticity, there exists specific orientations of the wavevector for which a perfect helicity mismatch is reached. The spin waves with this orientation and this direction of wavevector are "dark" in the sense that they do not couple with the inductive antenna. This leads to single-sided wavevector generation, that should not to be confused with a unidirectional emission of energy. A method to calculate the antenna-to-antenna transmission parameter is then provided. Analytical approximations are then applied on situations that illustrate the respective role of the direction of the spin wave wavevector versus that of the group velocity. The often-encountered cases of spin waves possessing either a V-shaped or a flat dispersion relation are revisited. These reciprocal dispersion relations lead to amplitude non-reciprocity because of the helicity mismatch phenomenon. Conversely, for spin waves with a line-shaped dispersion relation, a quasi-unidirectional emission of spin waves occurs. This situation can be obtained when using the acoustical spin waves of synthetic antiferromagnets when the wavevector is close to parallel to the applied field. We finally show that this configuration can be harnessed to design reconfigurable frequency filters.