Phononic Band Structure Engineering for High-Q Gigahertz Surface Acoustic Wave Resonators on Lithium Niobate

Linbo Shao, Smarak Maity, Lu Zheng, Lue Wu, Amirhassan Shams-Ansari, Young-Ik Sohn, Eric Puma, M.N. Gadalla, Mian Zhang, Cheng Wang, Evelyn Hu, Keji Lai, and Marko Lončar

Phys. Rev. Applied 12, 014022 – Published 12 July 2019

Abstract

Phonons at gigahertz frequencies interact with electrons, photons, and atomic systems in solids, and therefore, have extensive applications in signal processing, sensing, and quantum technologies. Surface acoustic wave (SAW) resonators that confine surface phonons can play a crucial role in such integrated phononic systems due to small mode size, low dissipation, and efficient electrical transduction. To date, it has been challenging to achieve a high quality (Q) factor and small phonon mode size for SAW resonators at gigahertz frequencies. We present a methodology to design compact high-Q SAW resonators on lithium niobate operating at gigahertz frequencies. We experimentally verify designs and demonstrate Q factors in excess of $2 \times 10^{4}$ at room temperature ( $6 \times 10^{4}$ at 4 Kelvin) and mode size as low as 1.87 $λ^{2}$ . This is achieved by phononic band structure engineering, which provides high confinement with low mechanical loss. The frequency Q products (fQ) of our SAW resonators are greater than $10^{13}$ . These high-fQ and small mode size SAW resonators could enable applications in quantum phononics and integrated hybrid systems with phonons, photons, and solid-state qubits.

Received 17 December 2018
Revised 23 March 2019

DOI:https://doi.org/10.1103/PhysRevApplied.12.014022

Physics Subject Headings (PhySH)

Band gap Phonons Piezoelectricity Quantum information with hybrid systems Quantum networks

Micromechanical devices Transition metal oxides

Surface acoustic wave

Interdisciplinary PhysicsCondensed Matter, Materials & Applied Physics

Authors & Affiliations

Linbo Shao ^1,*, Smarak Maity¹, Lu Zheng², Lue Wu¹, Amirhassan Shams-Ansari¹, Young-Ik Sohn¹, Eric Puma¹, M.N. Gadalla¹, Mian Zhang¹, Cheng Wang¹, Evelyn Hu¹, Keji Lai², and Marko Lončar^1,†

¹John A. Paulson School of Engineering and Applied Sciences, Harvard University, 29 Oxford Street, Cambridge, Massachusetts 02138, USA
²Department of Physics, University of Texas at Austin, Austin, Texas 78712, USA

^*shaolb@seas.harvard.edu
^†loncar@seas.harvard.edu

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Vol. 12, Iss. 1 — July 2019

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Images

Figure 1
SAW resonator on lithium niobate. (a) Illustration of band structure engineered surface acoustic resonator on lithium niobate. Inset: optical microscope image of a fabricated device. The dark region at the center is the etched grooves, and the bright regions on the sides are metal IDTs. (b) Scanning electron microscope image of the cavity part on lithium niobate. (c) Crosssection showing the etched grooves at the cavity part. A platinum layer is deposited to protect the surface of lithium niobate (LN) from damage during focused ion beam milling. (d) Surface profile of the SAW resonator scanned by atomic force microscopy.
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Figure 2
Phononic band structure engineering of SAW on lithium niobate. (a) Schematic of the SAW resonator and its design parameters. (b–d) Phononic band structures for SAW on unperturbed free surface, surface phononic crystal (PnC) part, and cavity part. The wave number k_x is normalized to the π phase of PnC. The vertical red dash line indicates the π of the cavity part, which is of a greater period. The design parameters are: etch width 0.653 µm, etch depth 115 nm, period for PnC part 1.92 µm, and period for cavity part 1.98 µm. (e) SAW modes of free surface and PnC with π phase of the unit cells. (f) Mode profiles of the fundamental and second-order modes of the SAW resonator. The color scale indicates the total energy density of electromagnetic, kinetic, and elastic energy densities.
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Figure 3
Experimental measurements of high-Q SAW resonator on LN. (a) Transmission measurements of a SAW resonator and an unperturbed free surface using a pair of IDT. Two high-Q modes, labeled 1 and 2, are observed in the band gap of the PnC. (b) Fine scans of transmission measurements for Mode 1 in atmosphere and vacuum. The measured data (dots) are fitted to Lorentzian peaks (lines). (c) Resonator ring down measurement of Mode 1 showing a lifetime of 2.69 µs. Inset: the voltage oscillation around 5 µs. (d) Measurements of Q factors and coupling intensities of Mode 1 of resonators with different numbers of PnC periods. Coupling intensity is measured as the peak height in transmission. (e) Measurements of SAW mode profiles using transmission-mode microwave impedance microscopy, showing mode profiles as a fundamental mode for Mode 1, and a second-order mode for Mode 2. This is the top view of the device.
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Figure 4
Low-temperature measurements of SAW resonators. Transmission (|S₂₁|²) of the fundamental mode measured during the sample cooling down by continuous flow liquid helium, and the temperature is monitored by a thermal coupler on the sample mount. Inset: A fine scan of the fundamental mode at the stabilized temperature of 4 K.
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Figure 5
Q factors on resonant frequencies of SAW resonators in atmosphere. The fundamental modes and the second-order modes are marked in blue circles and red stars, respectively. The color scale represents the number of PnC periods fabricated to confine the SAW modes.
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