High-Q single crystal silicon HARPSS capacitive beam resonators with self-aligned sub-100-nm transduction gaps

Pourkamali, Siavash; Hashimura, Akinori; Abdolvand, Reza; Ho, G.K.; Erbil, A.; Ayazi, Farrokh

doi:10.1109/jmems.2003.811726

Cited by 154 publications

(88 citation statements)

References 19 publications

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“…If it is assumed that the tracking spacing, track width and thickness are equal, then the coil resistance for a single layer, microfabricated coil can be expressed as; (11) For large N, the N 2 and N terms can be neglected. The dependence of the coil resistance on the cube of the number of turns arises in this case, from the fact that the turn cross-sectional area decreases with the number of turns squared, i.e.…”

Section: Coil Parametersmentioning

confidence: 99%

Scaling effects for electromagnetic vibrational power generators

O’Donnell¹,

Saha²,

Beeby

et al. 2007

Microsyst Technol

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Section: Coil Parametersmentioning

confidence: 99%

Scaling effects for electromagnetic vibrational power generators

O’Donnell¹,

Saha²,

Beeby

et al. 2007

Microsyst Technol

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“…A number of electrical coupling techniques [6][7][8] for implementation of high-order bandpass filters have been demonstrated with beam resonators [9]. The electrostatic coupling technique [9] can be employed to demonstrate second order IF filters.…”

Section: Electrostatically Coupled If Filtersmentioning

confidence: 99%

“…The electrostatic coupling technique [9] can be employed to demonstrate second order IF filters. In this technique, application of different bias voltages to the vibrating body of two resonators separated by a narrow coupling gap generates an electrostatic coupling force.…”

Section: Electrostatically Coupled If Filtersmentioning

confidence: 99%

High-Aspect-Ratio SOI Vibrating Micromechanical Resonators and Filters

Ayazi

Pourkamali

et al. 2006

2006 IEEE MTT-S International Microwave Symposium Digest

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-This paper presents a review of single crystal silicon bulk acoustic wave resonators and filters. Silicon-oninsulator (SOI) substrates are utilized to implement high quality factor (Q) integrated silicon resonators with capacitive and/or piezoelectric transducers. These resonators cover a wide range of frequencies including HF, VHF and UHF.Index Terms -Micromechanical resonators, SOI, micromechanical filters, bulk acoustic wave resonator, MEMS.

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“…Clamping losses to the substrate can be avoided by locating the support at a nodal point of the vibration mode or using impedance-mismatched supports to reflect energy back [16]. Thermoelastic dissipation (heat flow resulting from nonuniform strain) can be reduced by shrinking device size, using stiff, high thermal conductivity materials (Si, diamond) [19] or utilizing modes with uniform compression/expansion [20]. Surface loss mechanisms can be minimized by avoiding layered structures (thin-film interfaces) at surfaces.…”

Section: Energy Efficiency Considerationsmentioning

confidence: 99%

CMOS-MEMS resonator as a signal generator for fully-adiabatic logic circuits

Frank

Xie

2005

Smart Structures, Devices, and Systems II

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Fully-adiabatic (thermodynamically reversible) logic is one of the few promising approaches to low-power logic design. To maximize the system power-performance of an adiabatic circuit requires an ultra low-loss on-chip clock source, which can generate an output signal with a quasi-trapezoidal (flat-topped) voltage waveform. In this paper, we propose to use high-Q MEMS resonators to generate the custom waveform. The big challenge in the MEMS resonator design is that a non-sinusoidal (quasi-trapezoidal) waveform needs to be generated even though the resonator oscillates sinusoidally. Our solution is to customize the shape of the sensing comb fingers of the resonator, with the result that the sensing capacitance varies quasi-trapezoidally. The effective quality factor and the area-efficiency of the microstructure have been optimized so as to minimize the whole system's power dissipation and cost at a given frequency. A resonator design with a 100 kHz resonant frequency based on a standard TSMC 0.35µm CMOS process has been fabricated. The resonator has an area of 300 µm by 160 µm with a thickness of 30 µm. Three-dimensional field simulation shows that the resonator generates a quasi-trapezoidal waveform when it operates at its resonance. An on-chip buffer is also designed for monitoring the waveform generated by the MEMS resonator. The post-CMOS fabrication process is compatible with standard CMOS processes. Thus the custom clock generator can be integrated with logic circuits on the same CMOS chip. The size of the MEMS resonator can be further reduced by design optimization and advances in micro/nano-fabrication technology.

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High-Q single crystal silicon HARPSS capacitive beam resonators with self-aligned sub-100-nm transduction gaps

Cited by 154 publications

References 19 publications

Scaling effects for electromagnetic vibrational power generators

Scaling effects for electromagnetic vibrational power generators

High-Aspect-Ratio SOI Vibrating Micromechanical Resonators and Filters

CMOS-MEMS resonator as a signal generator for fully-adiabatic logic circuits

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