What question did this study set out to answer?

The aim is to explore how spin waves can be excited in ferrimagnetic materials using a novel optical technique.

February 14, 2026Open Access

Excitation of Spin Waves in Ferrimagnetic Alloy via Optical Transient Grating Spectroscopy

Key Points

The aim is to explore how spin waves can be excited in ferrimagnetic materials using a novel optical technique.
Utilized an all-optical transient grating approach
Employed two coherent laser pulses for excitation
Probed spin waves through diffraction of a third pulse
Analyzed signals via polarization to distinguish between magnetic and thermoelastic effects
Successfully excited spin waves with a wavelength of 2.5 μm
Controlled the in-plane wave vector effectively
Enabled time-resolved observations of spin-wave dynamics

Abstract

The investigation of spin waves provides fundamental insights into magnetic materials and is essential for advancing spintronic and magnonic technologies. The Transient Grating (TG) technique, a four‐wave mixing method, has been widely used to study collective excitations at controlled wave vectors on the micron to nanometer scale. This study presents an all‐optical TG approach for exciting standing dipolar spin waves with a controlled in‐plane wave vector in a ferrimagnetic Co 78 Gd 22 thin film, with potential applicability to a broad range of materials. Spin waves with a wavelength of 2.5 μm are excited by the interference of two coherent laser pulses on the sample surface and probed through the diffraction of a third laser pulse. Polarization analysis separates magnetic and thermoelastic signals and enables time‐resolved measurements of the spin‐wave dynamics.

Excitation of Spin Waves in Ferrimagnetic Alloy via Optical Transient Grating Spectroscopy

Key Points

Abstract

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