Generation of a single-cycle surface acoustic wave pulse on LiNbO$_3$ for application to thin film materials

TL;DR

This paper demonstrates efficient generation of high-intensity, single-cycle surface acoustic wave pulses on LiNbO$_3$ using chirp interdigital transducers, enabling advanced studies in thin film materials and quasi-particle dynamics.

Contribution

It introduces a novel method for generating high-intensity, single-cycle SAW pulses on LiNbO$_3$ with high efficiency, surpassing previous substrates like GaAs.

Findings

SAW pulse with 0.3 ns FWHM achieved

Conversion efficiency 45 times higher than GaAs

Bandwidths from 0.5 GHz to 5.5 GHz demonstrated

Abstract

Surface acoustic wave (SAW) technology has been explored in thin-film materials to discover fundamental phenomena and to investigate their physical properties. It is used to excite and manipulate quasi-particles such as phonons or magnons, and can dynamically modulate the properties of the materials. In the field, SAWs are typically excited by a continuous wave at a resonant frequency. Recently, generation of a single-cycle SAW pulse has been demonstrated on GaAs substrate. Such a SAW pulse provides a potential to access a single quasi-particle excitation and to investigate its dynamics by time-resolved measurements. On the other hand, to modulate and control the properties of thin film materials, it is generally required to generate high-intensity SAWs. In this work, we demonstrate the efficient generation of a SAW pulse using a chirp interdigital transducer (IDT) on LiNbO$_3$ substrate. We have fabricated chirp IDT devices with bandwidths from 0.5 GHz to 5.5 GHz. We also confirmed the generation of a SAW pulse with 0.3 ns FWHM (full width at half maximum) by performing time-resolved measurements. The conversion efficiency between input power and SAW on LiNbO$_3$ substrate is approximately 45 times larger than that on GaAs substrate. This enables us to generate a high-intensity SAW pulse, meeting the requirement for the modulation of thin films. Our results will expand the research in the field, such as spintronics and magnonics, and lead to their further advancements.