Super-high-frequency two-port AlN contour-mode resonators for RF applications

Rinaldi, Matteo; Zuniga, C.; Zuo, Chengjie; Piazza, Gianluca

doi:10.1109/tuffc.2010.1376

Cited by 213 publications

(109 citation statements)

References 14 publications

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“…In fact, the presence of water introduces a large parasitic capacitance, C p (~ 680 fF), in parallel to the device geometrical capacitance, C 0 , which, as highlighted in [9], negatively affects the k t 2 of the device (k t 2 ∝C m /C 0 ). It is possible to observe ( Table I) that, when the PRN is employed, the value of such parasitic parallel capacitance, C p , is significantly reduced (C p ~38 fF) and negligible if compared to the device capacitance, C 0 .…”

Section: Designmentioning

confidence: 99%

High frequency Piezoelectric Resonant Nanochannel for bio-sensing applications in liquid environment

2010

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This paper reports on the first demonstration of a 457 MHz AlN Piezolectric Resonant Nanochannel (PRN) for biosensing applications in liquid environment. A novel process consisting of 7 lithographic steps was developed to fabricate the PRN. The new resonant device shows an unchanged value of the electromechanical coupling, k t 2 (about 0.8 %), whether the channel is filled with air or water and a quality factor, Q, in liquid of approximately 170.

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Section: Designmentioning

confidence: 99%

High frequency Piezoelectric Resonant Nanochannel for bio-sensing applications in liquid environment

2010

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“…Such high Figure The achievement of a high value of device FOM is of crucial importance for the direct connection of the ovenized MEMS resonator to a compact and low-power oscillator circuit. In fact, the primary power loss in an oscillator circuit is due to the motional resistance, R m , of the resonator, the value of which is inversely proportional to the device FOM (R m ∝1/(C 0 ⋅k t 2 ⋅Q)) [7].…”

Section: Resultsmentioning

confidence: 99%

“…By reducing the thickness of the AlN plate (i.e. implementing a nano-plate) the lateral dimensions of the device can be scaled maintaining high transduction efficiency [7]. Therefore, in order to maximize the device performance it is crucial to scale the volume of the AlN resonant nano-plate maintaining, at the same time, high quality factor and power handling.…”

Section: A Theoretical Modelingmentioning

confidence: 99%

“…Therefore, in order to maximize the device performance it is crucial to scale the volume of the AlN resonant nano-plate maintaining, at the same time, high quality factor and power handling. According to the aforementioned design considerations, the thickness of the AlN nano-plate resonator of this work was set to 500 nm and its lateral dimensions were properly designed in order to maintain a low value of the device equivalent electrical impedance [7]. The device was designed to operate at high frequency (~ 1 GHz), which guarantees high power handling of the mechanical structure [8].…”

Section: A Theoretical Modelingmentioning

confidence: 99%

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Ultra-fast and high resolution NEMS thermal detector based on a nano-air-gap piezoelectric resonant structure

Huang

Rinaldi

2012

2012 IEEE Sensors

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Abstract-This paper presents the theoretical modeling and experimental verification of an innovative Nano Electro Mechanical System (NEMS) technology suitable for the implementation of ultra-fast and high resolution un-cooled thermal detectors. Fundamental challenges associated to the implementation of mechanically resonant thermal detectors are overcome with the introduction of an innovative technology platform in which a temperature sensitive Aluminum Nitride (AlN) nano-plate resonator and a monolithically integrated micromachined suspended heat absorbing element are perfectly overlapped but separated by a sub-micron air gap. By placing the absorbing element outside the body of the resonator (but suspended over it) the electromechanical performance of the resonant device is not affected by the absorbing element and the material employed to implement it (quality factor, Q≈1800 and electromechanical coupling coefficient, k t 2 ≈1%) enabling the use of a compact and low-power self-sustained oscillator circuit as direct frequency readout. At the same time, efficient and quick heat transfer from the absorbing element to the nanomechanical resonant device is achieved by minimizing the air gap between them. The detection capabilities of this first prototype were tested using an integrated resistive heat source in lieu of an absorber. Power level as low as 655 nW was readily detected and a limit of detection of 48 nW was experimentally extracted. In addition a thermal time constant of ~ 60 μs was predicted for this prototype through finite element simulation.

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“…Such high values (~ 20) of the device figure of merit, k t 2 ⋅Q, are of crucial importance for the direct connection of multiple CMR-S to a compact and low power multiplexed oscillator circuit for direct frequency read-out. In fact, the primary power loss in such oscillator circuit is due to the motional resistance, R m , of the resonator [10], whose value is inversely proportional to the device figure of merit, k t 2 ⋅Q [11,12].…”

Section: A Nano-cmr-s Arraymentioning

confidence: 99%

Use of a single multiplexed CMOS oscillator as direct frequency read-out for an array of eight AlN Contour-Mode NEMS Resonant Sensors

et al. 2010

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Gianluca; , "Use of a single multiplexed CMOS oscillator as direct frequency read-out for an array of eight AlN Contour-Mode NEMS Resonant Sensors," Sensors, 2010 IEEE , vol., no., pp.2666-2670, 1-4 Nov. 2010 ©2010 IEEE. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE. This paper reports on the first demonstration of a single multiplexed CMOS oscillator circuit employed as direct frequency readout for an array of 8 nanoscaled aluminum nitride Contour-Mode Resonant Sensors (CMR-S). In this first prototype 8 thin-film (250 nm) AlN CMR-S operating at 186 MHz were fabricated on the same chip and simultaneously wire-bonded to a Pierce-like oscillator circuit (fabricated in the ON Semiconductor 0.5 µm CMOS process) by means of 8 CMOS transmission gates addressed via a 3 bit on-chip decoder. The 8 CMR-S were simultaneously exposed to different concentrations of methanol (0.1-1% of the saturated vapor pressure) and their response was monitored in a time-multiplexed mode. Frequency shifts of 300 Hz corresponding to changes of mass per unit area of 7 ag/µm 2 were experimentally detected. Values of phase noise derived Allan deviation as low as 0.9 Hz were measured. Such Allan deviation translates in an estimated limit of detection of 21 zg/µm 2 . Disciplines Engineering | Engineering Science and Materials CommentsSuggested Citation: Rinaldi, Matteo; Zuniga, Chiara; Duick, Brandon; Piazza, Gianluca; , "Use of a single multiplexed CMOS oscillator as direct frequency read-out for an array of eight AlN Contour-Mode NEMS Resonant Sensors," Sensors, 2010 IEEE , vol., no., pp.2666-2670, 1-4 Nov. 2010. ©2010 IEEE. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE.

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Super-high-frequency two-port AlN contour-mode resonators for RF applications

Cited by 213 publications

References 14 publications

High frequency Piezoelectric Resonant Nanochannel for bio-sensing applications in liquid environment

High frequency Piezoelectric Resonant Nanochannel for bio-sensing applications in liquid environment

Ultra-fast and high resolution NEMS thermal detector based on a nano-air-gap piezoelectric resonant structure

Use of a single multiplexed CMOS oscillator as direct frequency read-out for an array of eight AlN Contour-Mode NEMS Resonant Sensors

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