Monocrystalline Silicon Carbide Disk Resonators on Phononic Crystals with Ultra-Low Dissipation Bulk Acoustic Wave Modes

Hamelin, Benoit; Yang, Jeremy; Daruwalla, Anosh; Wen, Haoran; Ayazi, Farrokh

doi:10.1038/s41598-019-54278-9

Cited by 34 publications

(19 citation statements)

References 28 publications

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“…To examine whether alternative materials could allow for better performing resonators in the future, we consider silicon carbide, [ 48,120,121 ] graphene, [ 15,104,122 ] and diamond, [ 123–125 ] comparing their upper‐bounds of performance relative to silicon nitride. The upper‐bounds are calculated by assuming the material's intrinsic quality factor is the highest experimentally demonstrated to our knowledge at room temperature, [ 121,123,126 ] and their dissipation dilution limit is set by the material yield stress, [ 48,117,127 ] as described in ref. [46].…”

Section: Strain Engineeringmentioning

confidence: 99%

Nanomechanical Dissipation and Strain Engineering

Sementilli

Romero

Bowen

2021

Adv Funct Materials

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Nanomechanical resonators have applications in a wide variety of technologies ranging from biochemical sensors to mobile communications, quantum computing, inertial sensing, and precision navigation. The quality factor of the mechanical resonance is critical for many applications. Until recently, mechanical quality factors rarely exceeded a million. In the past few years however, new methods have been developed to exceed this boundary. These methods involve careful engineering of the structure of the nanomechanical resonator, including the use of acoustic bandgaps and nested structures to suppress dissipation into the substrate, and the use of dissipation dilution and strain engineering to increase the mechanical frequency and suppress intrinsic dissipation. Together, they have allowed quality factors to reach values near a billion at room temperature, resulting in exceptionally low dissipation. This review aims to provide a pedagogical introduction to these new methods, primarily targeted to readers who are new to the field, together with an overview of the existing state‐of‐the‐art, what may be possible in the future, and a perspective on the future applications of these extreme‐high quality resonators.

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Section: Strain Engineeringmentioning

confidence: 99%

Nanomechanical Dissipation and Strain Engineering

Sementilli

Romero

Bowen

2021

Adv Funct Materials

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“…However, there was a consistent discrepancy between our measurement and theoryparticularly in elliptical wineglass modes; this motivated investigation into a new set of elastic constants that better reflect the mechanical properties of 4H-SiC within the framework of the SiCOI platform. As described earlier, achieving high Q is non-trivial often due to anchor losses which rely on a thorough understanding of 4H-SiC's stiffness to conform to various decoupling schemes' stringent frequency requirements [18], [20].…”

Section: B Elastic Anisotropy Refinementmentioning

confidence: 99%

“…The recent development of bond and etch-back thick monocrystalline 4H silicon carbide-on-insulator (4H-SiCOI) substrates [17] and their deep reactive ion etching with high aspect ratio [18], [19] facilitate wafer-level fabrication of capacitive in-plane resonators with ultra-high mechanical Q-factors. Their frequency spectrum measurements have revealed that the elasticity of hexagonal 4H-SiC is not well-understood, evidenced by consistent discrepancy with numerical simulations from wafer to wafer [20].…”

Section: Introductionmentioning

confidence: 99%

Investigating Elastic Anisotropy of 4H-SiC Using Ultra-High Q Bulk Acoustic Wave Resonators

Yang

Hamelin

Ayazi

2020

J. Microelectromech. Syst.

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Hexagonal 4H-silicon carbide (4H-SiC) is a transversely isotropic substrate garnering interest for precision MEMS devices such as resonant gyroscopes. This paper investigates the elastic anisotropy of 4H-SiC by utilizing capacitive bulk acoustic wave (BAW) resonators with ultra-high mechanical quality factors ( Q) enabled by phononic crystals. We directly measure the value of C 66 using Lamé mode resonators for the first time and numerically fit the values of C 11 and C 12 using BAW elliptical modes in center-supported solid disk resonators. We compare (0 0 0 1) 4H-SiC to (1 1 1) Si, another in-plane isotropic material and validate (0 0 0 1) 4H-SiC's superior robustness to fabrication and design variations. Measurement of in-plane BAW elliptical modes in multiple disk resonators with as-born frequency splits as low as 3 ppm reveal (0 0 0 1) 4H-SiC's transverse isotropy across process corners. Lamé mode resonators display a temperature coefficient of frequency (TCF) three times lower compared to its Si counterpart. Finally, this paper provides a modified set of elastic constants for 4H-SiC with a view towards monocrystalline SiC MEMS devices.

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“…As a new generation gyroscope, the micro-electro-mechanical system disk resonator gyroscope (MEMS DRG) is an attractive candidate for high-performance MEMS gyroscopes due to its near navigational grade precision and small volume [ 1 , 2 , 3 , 4 , 5 ]. As a solid wave gyroscope (SWG), MEMS DRG inherently possesses a high Q factor and mode match mechanism, which maintain its low mechanical-thermal noise and high mechanical sensitivity [ 6 , 7 , 8 , 9 ].…”

Section: Introductionmentioning

confidence: 99%

Study of the Influence of Phase Noise on the MEMS Disk Resonator Gyroscope Interface Circuit

Zhang

Chen

Yin

et al. 2020

Sensors

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In this paper, a detailed analysis of the influence of phase noise on the micro-electro-mechanical system (MEMS) disk resonator gyroscope (DRG) is presented. Firstly, a new time-varying phase noise model for the gyroscope is established, which explains how the drive loop circuit noise converts into phase noise. Different from previous works, the time-varying phase noise model in this paper is established in mechanical domain, which gain more physical insight into the origin of the phase noise in gyroscope. Furthermore, the impact of phase noise on DRG is derived, which shows how the phase noise affects angular velocity measurement. The analysis shows that, in MEMS DRG, the phase noise, together with other non-ideal factors such as direct excitation of secondary resonator, may cause a low frequency noise in the output of the gyroscope system and affect the bias stability of the gyroscope. Finally, numerical simulations and experiment tests are designed to prove the theories above.

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Monocrystalline Silicon Carbide Disk Resonators on Phononic Crystals with Ultra-Low Dissipation Bulk Acoustic Wave Modes

Cited by 34 publications

References 28 publications

Nanomechanical Dissipation and Strain Engineering

Nanomechanical Dissipation and Strain Engineering

Investigating Elastic Anisotropy of 4H-SiC Using Ultra-High Q Bulk Acoustic Wave Resonators

Study of the Influence of Phase Noise on the MEMS Disk Resonator Gyroscope Interface Circuit

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