Litcius/Paper detail

Surface modification and coherence in lithium niobate SAW resonators

Rachel G. Gruenke, Oliver A. Hitchcock, E. Alex Wollack, Christopher J. Sarabalis, Marc Jankowski, Timothy P. McKenna, Nathan Lee, Amir H. Safavi‐Naeini

2024Scientific Reports14 citationsDOIOpen Access PDF

Abstract

Lithium niobate is a promising material for developing quantum acoustic technologies due to its strong piezoelectric effect and availability in the form of crystalline thin films of high quality. However, at radio frequencies and cryogenic temperatures, these resonators are limited by the presence of decoherence and dephasing due to two-level systems. To mitigate these losses and increase device performance, a more detailed picture of the microscopic nature of these loss channels is needed. In this study, we fabricate several lithium niobate acoustic wave resonators and apply different processing steps that modify their surfaces. These treatments include argon ion sputtering, annealing, and acid cleans. We characterize the effects of these treatments using three surface-sensitive measurements: cryogenic microwave spectroscopy measuring density and coupling of TLS to mechanics, X-ray photoelectron spectroscopy and atomic force microscopy. We learn from these studies that, surprisingly, increases of TLS density may accompany apparent improvements in the surface quality as probed by the latter two approaches. Our work outlines the importance that surfaces and fabrication techniques play in altering acoustic resonator coherence, and suggests gaps in our understanding as well as approaches to address them.

Topics & Concepts

Lithium niobateResonatorDephasingMaterials scienceX-ray photoelectron spectroscopySurface acoustic waveCoherence (philosophical gambling strategy)PiezoelectricityOptoelectronicsFabricationThin filmNanotechnologyAcousticsCondensed matter physicsPhysicsNuclear magnetic resonanceComposite materialAlternative medicinePathologyMedicineQuantum mechanicsAcoustic Wave Resonator TechnologiesMechanical and Optical ResonatorsPhotorefractive and Nonlinear Optics