Self-Oscillations in Field Emission Nanowire Mechanical Resonators:  A Nanometric dc−ac Conversion

Ayari, A.; Vincent, P.; Perisanu, S.; Choueib, M.; Gouttenoire, V.; Bechelany, Mikhaël; Cornu, David; Purcell, Stephen T.

doi:10.1021/nl070742r

Cited by 93 publications

(88 citation statements)

References 21 publications

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“…A lot of effort has been devoted to developing new transduction and background reduction [6]. A variety of NEMS detection techniques, such as capacitive [3,7,8], magnetomotive [9], piezoresistive [10,11] and field-emission [4,12] transduction, have been proposed. The magnetomotive approach typically requires large magnetic fields (2-8 T) and is thus not suitable for integrated applications.…”

Section: Introductionmentioning

confidence: 99%

In-plane nanoelectromechanical resonators based on silicon nanowire piezoresistive detection

et al. 2010

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We report an actuation/detection scheme with a top-down nanoelectromechanical system (NEMS) for frequency shift based sensing applications with outstanding performance. It relies on electrostatic actuation and piezoresistive nanowire gauges for in-plane motion transduction. The process fabrication is fully CMOS (complementary metal-oxide-semiconductor) compatible. The results show a very large dynamic range of more than 100 dB and an unprecedented signal to background ratio of 69 dB providing an improvement of two orders of magnitude in the detection efficiency presented in the state of the art in NEMS fields. Such a dynamic range results from both negligible 1/ f noise and very low Johnson noise compared to the thermomechanical noise. This simple low power detection scheme paves the way for new class of robust mass resonant sensors.

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Section: Introductionmentioning

confidence: 99%

In-plane nanoelectromechanical resonators based on silicon nanowire piezoresistive detection

et al. 2010

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“…A few experiments are reported about free thermal vibration of the nanoscale cantilevered and suspended structure. Non planar motion of free vibration [7] and forced vibration [8] is measured using the field emission method (FEM) in silicon nanowire. We show that poincare distribution and frequency response in fine resolution shows this doffing (nonplanar) motion satisfies the solution of continuum non-linear equation which is derived by Hamilton's extended principle [9].…”

Section: Introductionmentioning

confidence: 99%

Non-linear and Non-planar Free Thermal Vibration of SWNT in Molecular Dynamic Simulation

Koh

Cannon

Chiashi

et al. 2012

Extended Abstracts of the 2012 International Conference on Solid State Devices and Materials

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IntroductionVibration of suspended and cantilevered nanotubes and nanowires has been studied extensively in electronics circuits such as transistor, mixer[1], sensors [2][3] and mesoscopic quantum theory [4]. Recently, it is reported that the power spectrum of the free thermal vibration of cantilevered single walled carbon nanotubes (SWNT) can be well expressed by Euler beam and Timoshenko beam theory and the continuous mechanics portion of the motion among the total thermal energy is about 97 percent [5][6]. The beam motion and thermal vibrational motion are strongly coupled for nanoscale structures. Vibrational motion or temperature can evolve to the beam motion. We observed that there is nonplanar motion with beating and bifurcation with long time span in NVE condition using molecular dynamics (MD) calculation. A few experiments are reported about free thermal vibration of the nanoscale cantilevered and suspended structure. Non planar motion of free vibration [7] and forced vibration [8] is measured using the field emission method (FEM) in silicon nanowire. We show that poincare distribution and frequency response in fine resolution shows this doffing (nonplanar) motion satisfies the solution of continuum non-linear equation which is derived by Hamilton's extended principle [9].

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“…The strong electrostatic influence on the mechanics opens the perspective for coupled self oscillations in this configuration, as previously observed on individual NNs under Field Emission. [15][16][17] This work is supported by the French National Research Agency ͑ANR͒ through the Nanoscience and Nanotechnology Program ͑Project NEXTNEMS No. ANR-07-NANO-008-01 and Project NEMSPiezo No.…”

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confidence: 99%

The mechanical resonances of electrostatically coupled nanocantilevers

Perisanu

Barois

Poncharal

et al. 2011

Applied Physics Letters

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International audienceWe present here an experimental study of the electrostatic coupling between the mechanical resonances of two nanowires or two nanotubes. This coupling occurs when the eigenfrequencies of the two resonators are matched by electrostatic tuning and it changes from a weak coupling to a strong coupling regime as the distance between the cantilevers is decreased. Linear coupling theory is shown to be in excellent agreement with the experimental data

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Self-Oscillations in Field Emission Nanowire Mechanical Resonators: A Nanometric dc−ac Conversion

Cited by 93 publications

References 21 publications

In-plane nanoelectromechanical resonators based on silicon nanowire piezoresistive detection

In-plane nanoelectromechanical resonators based on silicon nanowire piezoresistive detection

Non-linear and Non-planar Free Thermal Vibration of SWNT in Molecular Dynamic Simulation

The mechanical resonances of electrostatically coupled nanocantilevers

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