High-frequency surface acoustic wave devices at very low temperature: Application to loss mechanisms evaluation

Habti, A. El; Baudin, François; Bigler, E.; Thorvaldsson, T.

doi:10.1121/1.415953

Cited by 10 publications

(10 citation statements)

References 2 publications

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“…An average value of 6 dB mm À 1 is obtained, which should be considered as an upper bound estimation of the propagation loss, because effects such as the reflection of the acoustic wave by the waveguide are not considered in the calculation. With this apparently high value of linear loss 35,36 , the total acoustic loss, however, is insignificant, considering that the footprint of photonic devices typically spans only a few tens of micrometres. Although the interference effect can be used to enhance A/O modulation at a specific frequency, the large passband ripples are undesirable for signal processing applications.…”

Section: Resultsmentioning

confidence: 99%

Sub-optical wavelength acoustic wave modulation of integrated photonic resonators at microwave frequencies

Tadesse¹,

Li²

2014

Nat Commun

169

103

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Light-sound interactions have long been exploited in various acousto-optic devices based on bulk crystalline materials. Conventionally, these devices operate in megahertz frequency range where the acoustic wavelength is much longer than the optical wavelength and a long interaction length is required to attain significant coupling. With nanoscale transducers, acoustic waves with sub-optical wavelengths can now be excited to induce strong acoustooptic coupling in nanophotonic devices. Here we demonstrate microwave frequency surface acoustic wave transducers co-integrated with nanophotonic resonators on piezoelectric aluminum nitride substrates. Acousto-optic modulation of the resonance modes at above 10 GHz with the acoustic wavelength significantly below the optical wavelength is achieved. The phase and modal matching conditions in this scheme are investigated for efficient modulation. The new acousto-optic platform can lead to novel optical devices based on nonlinear Brillouin processes and provides a direct, wideband link between optical and microwave photons for microwave photonics and quantum optomechanics.

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Section: Resultsmentioning

confidence: 99%

Sub-optical wavelength acoustic wave modulation of integrated photonic resonators at microwave frequencies

Tadesse¹,

Li²

2014

Nat Commun

169

103

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“…Q m refers to losses due to interaction with thermal phonons, losses due to defects in the material, and propagation losses due to contamination [37,38]. These losses ultimately limit Q: Low-temperature experiments on quartz have demonstrated SAW resonators with Q m × f½GHz > 10 5 [22,23]. Another source of losses is due to mode conversion into bulk modes.…”

Section: Appendix E: Saw Cavitiesmentioning

confidence: 99%

“…(3) Our scheme is built upon an established technology [14,15]: Lithographic fabrication techniques provide almost arbitrary geometries with high precision as evidenced by a large range of SAW devices such as delay lines, bandpass filters, resonators, etc. In particular, the essential building blocks needed to interface qubits with SAW phonons have already been fabricated, according to design principles familiar from electromagnetic devices: (i) SAW resonators, the mechanical equivalents of Fabry-Perot cavities, with low-temperature measurements reaching quality factors of Q ∼ 10 5 even at gigahertz frequencies [22][23][24], and (ii) acoustic waveguides as analog to optical fibers [14]. (4) For a given frequency in the gigahertz range, due to the slow speed of sound of ∼10 3 m=s for typical materials, device dimensions are in the micrometer range, which is convenient for fabrication and integration with semiconductor components, and about 10 5 times smaller than corresponding electromagnetic resonators.…”

Section: Introductionmentioning

confidence: 99%

Universal Quantum Transducers Based on Surface Acoustic Waves

et al. 2015

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We propose a universal, on-chip quantum transducer based on surface acoustic waves in piezoactive materials. Because of the intrinsic piezoelectric (and/or magnetostrictive) properties of the material, our approach provides a universal platform capable of coherently linking a broad array of qubits, including quantum dots, trapped ions, nitrogen-vacancy centers, or superconducting qubits. The quantized modes of surface acoustic waves lie in the gigahertz range and can be strongly confined close to the surface in phononic cavities and guided in acoustic waveguides. We show that this type of surface acoustic excitation can be utilized efficiently as a quantum bus, serving as an on-chip, mechanical cavity-QED equivalent of microwave photons and enabling long-range coupling of a wide range of qubits.

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“…Q m refers to losses due to interaction with thermal phonons, losses due to defects in the material and propagation losses due to contamination [36,37]. These losses ultimately limit Q: Low temperature experiments on quartz have demonstrated SAW resonators with Q m × f [GHz] > 10 5 [21,22]. Another source of losses is due to mode-conversion into bulk-modes.…”

Section: Appendix E: Saw Cavitiesmentioning

confidence: 99%

“…(3) Our scheme is built upon an established technology [14,15]: Lithographic fabrication techniques provide almost arbitrary geometries with high precision as evidenced by a large range of SAW devices such as delay lines, bandpass filters or resonators etc. In particular, the essential building blocks needed to interface qubits with SAW phonons have already been fabricated, according to design principles familiar from electromagnetic devices: (i) SAW resonators, the mechanical equivalents of Fabry-Perot cavities, with low-temperature measurements reaching quality factors of Q ∼ 10 5 even at gigahertz frequencies [21][22][23], and (ii) acoustic waveguides as analogue to optical fibers [14]. (4) For a given frequency in the gigahertz range, due to the slow speed of sound of approximately ∼ 10 3 m/s for typical materials, device dimensions are in micrometer range, which is convenient for fabrication and integration with semiconductor components, and about 10 5 times smaller than corresponding electromagnetic resonators.…”

Section: Introductionmentioning

confidence: 99%

Universal Quantum Transducers Based on Surface Acoustic Waves

Schütz

2016

Quantum Dots for Quantum Information Processing: Controlling and Exploiting the Quantum Dot Environment

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We propose a universal, on-chip quantum transducer based on surface acoustic waves in piezoactive materials. Because of the intrinsic piezoelectric (and/or magnetostrictive) properties of the material, our approach provides a universal platform capable of coherently linking a broad array of qubits, including quantum dots, trapped ions, nitrogen-vacancy centers or superconducting qubits. The quantized modes of surface acoustic waves lie in the gigahertz range, can be strongly confined close to the surface in phononic cavities and guided in acoustic waveguides. We show that this type of surface acoustic excitations can be utilized efficiently as a quantum bus, serving as an on-chip, mechanical cavity-QED equivalent of microwave photons and enabling long-range coupling of a wide range of qubits.

show abstract

High-frequency surface acoustic wave devices at very low temperature: Application to loss mechanisms evaluation

Cited by 10 publications

References 2 publications

Sub-optical wavelength acoustic wave modulation of integrated photonic resonators at microwave frequencies

Sub-optical wavelength acoustic wave modulation of integrated photonic resonators at microwave frequencies

Universal Quantum Transducers Based on Surface Acoustic Waves

Universal Quantum Transducers Based on Surface Acoustic Waves

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