Temperature-dependent acoustic loss at microwave frequencies in thin-film lithium niobate

TL;DR

This study systematically investigates temperature-dependent acoustic loss in thin-film lithium niobate across various platforms and modes, revealing loss mechanisms and guiding low-loss device design.

Contribution

It provides a comprehensive analysis of acoustic loss origins in TFLN, including temperature effects and interface impurities, which was previously not well understood.

Findings

Non-monotonic temperature dependence of acoustic loss in LNOI

Loss dominated by buried oxide layer at low temperatures

Akhiezer damping governs high-temperature loss

Abstract

Thin-film lithium niobate (TFLN) has emerged as a versatile platform for phononic and photonic devices with applications ranging from classical signal processing to quantum technologies. However, acoustic loss fundamentally limits the performance of acoustic devices on TFLN platforms, yet its physical origin remains insufficiently understood. Here, we systematically investigate acoustic propagation loss in various TFLN platforms, including lithium niobate on insulator (LNOI), lithium niobate on sapphire (LNOS), suspended LN thin films, and bulk LN at gigahertz frequencies over temperatures ranging from 4 K to above room temperature. Using a delay-line method, we extract frequency- and temperature-dependent losses for Rayleigh, shear-horizontal, and Lamb modes. We observe an anomalous non-monotonic temperature dependence in LNOI that closely resembles acoustic loss in amorphous materials, indicating a dominant loss channel associated with the buried oxide layer at low temperatures. At elevated temperatures, the loss converges to the Akhiezer damping governed by phonon-phonon interactions. High-resolution electron microscopy further reveals nanoscale interfacial crystal impurities that may contribute to the increased acoustic loss in TFLN platforms relative to bulk LN. These results elucidate the acoustic loss mechanisms in TFLN and provide guidelines for designing low-loss acoustic devices.