High-sensitivity linear piezoresistive transduction for nanomechanical beam resonators

Sansa, Marc; Fernández-Regúlez, Marta; Llobet, Jordi; Paulo, Álvaro San; Pérez‐Murano, F.

doi:10.1038/ncomms5313

Cited by 50 publications

(58 citation statements)

References 29 publications

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“…This pre-strain situation happens as a consequence of an asymmetric beam profile at rest. As it is demonstrated previously, 10 the larger the value of the pre-strain, the larger will be the piezoresistive transduced signal. This effect is more relevant in NEMS structure rather than in MEMS structure because the relative value of the pre-strain with respect to the strain induced during the oscillation is larger in small, ultra-thin beams.…”

Section: à2mentioning

confidence: 86%

“…10 The influence of the geometrical asymmetry of the devices on the electromechanical transduction is analyzed taking into account the model developed previously. 10 The onset of the linearized piezoresistive transduction occurs when the DCB is in a pre-strained situation in equilibrium, and then its longitudinal strain is modulated around this equilibrium position. This pre-strain situation happens as a consequence of an asymmetric beam profile at rest.…”

Section: à2mentioning

confidence: 99%

“…Recently, it has been shown that geometrical asymmetries present in DCBs cause an enhancement of the piezoresistive transduction, allowing to obtain large read-out electrical signals from silicon nanowire resonators obtained by top-down and bottom-up fabrication methods. 10 Here, we show that piezo-resistive read-out signals in DCB nanomechanical resonators can be tuned by engineering the asymmetry of the device, and in particular, by inducing deliberate asymmetries that enhance the transduction of specific resonant modes.…”

mentioning

confidence: 99%

“…The first fabrication step consists in local gallium implantation of the SOI layer by FIB, to define the silicon nanowire, the side gate electrode (when required), and the contact pads and lines (ii). The ion dose used for the implantation is 10 16 atÁcm…”

mentioning

confidence: 99%

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Tuning piezoresistive transduction in nanomechanical resonators by geometrical asymmetries

Llobet

Sansa

Lorenzoni

et al. 2015

Applied Physics Letters

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The effect of geometrical asymmetries on the piezoresistive transduction in suspended double clamped beam nanomechanical resonators is investigated. Tapered silicon nano-beams, fabricated using a fast and flexible prototyping method, are employed to determine how the asymmetry affects the transduced piezoresistive signal for different mechanical resonant modes. This effect is attributed to the modulation of the strain in pre-strained double clamped beams, and it is confirmed by means of finite element simulations. V C 2015 AIP Publishing LLC.[http://dx.doi.org/10.1063/1.4928709]Resonating nanomechanical structures are attractive building blocks for the realization of high performance sensors and integrated oscillators.1 For example, a double clamped nanometric beam (DCB) (a silicon nanowire or a carbon nanotube) presents very large resonance frequency and extremely low mass, which are both highly convenient to detect minuscule quantities of mass.2,3 Also, DCB 4 or more complex structures 5 can be integrated within CMOS circuits to build high frequency oscillators that eventually may substitute present hybrid and heterogeneous integration approaches for signal processing.The practical application of nanomechanical resonators requires an efficient method for detecting their oscillation, which becomes increasingly difficult as the dimensions of the structures shrink. Electrical read-out of the oscillation is one of the most straightforward ways of obtaining compact systems, enabling the possibility of simultaneous detection of a large number of resonating elements. Electrical transduction can be implemented, for example, by capacitive, 5 piezo-electric, 6 or piezo-resistive 7 read-out. Compared to other methods, piezoresistive read-out presents the advantage of easy implementation, since the beam itself acts as a piezoresistive gauge, simplifying device design and fabrication.While the so called giant piezoresistance effect has enabled piezoresistive read-out in DCB silicon nanowires fabricated by bottom-up methods, 8,9 it has not been observed in top-down fabricated DCBs. Recently, it has been shown that geometrical asymmetries present in DCBs cause an enhancement of the piezoresistive transduction, allowing to obtain large read-out electrical signals from silicon nanowire resonators obtained by top-down and bottom-up fabrication methods.10 Here, we show that piezo-resistive read-out signals in DCB nanomechanical resonators can be tuned by engineering the asymmetry of the device, and in particular, by inducing deliberate asymmetries that enhance the transduction of specific resonant modes.We have focused the present study on DCB nanomechanical resonators fabricated by a fast, accurate, and flexible prototyping method based on the combination of focused ion beam (FIB) exposure and wet silicon etching, 11 which is compatible with CMOS technology. 12 Next, we present the main details of the fabrication process, the electrical characterization setup, and the experimental results that show the influence of the geometri...

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Section: à2mentioning

confidence: 86%

Section: à2mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Tuning piezoresistive transduction in nanomechanical resonators by geometrical asymmetries

Llobet

Sansa

Lorenzoni

et al. 2015

Applied Physics Letters

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“…Hence, NWs serve as ultra-small mechanical components, where size reduction proves to be extra advantageous in sensing applications. The main advantages are associated with i) their high frequencies of operation leading to high sensitivities and high resolution, ii) their ability of deterministic integration with higherorder structures such as electrodes, and iii) the ease of their use as transducers, especially through piezoresistivity in Si NWs (Erdem Alaca, 2009;He and Yang, 2006;Sansa et al, 2014;Walther et al, 2012), and stretchable conductors with metal NWs (Xu and Zhu, 2012;Yao and Zhu, 2015).…”

Section: Introductionmentioning

confidence: 99%

Thermo-coupled Surface Cauchy–Born theory: An engineering finite element approach to modeling of nanowire thermomechanical response

Esfahani

Sonne

Hattel

et al. 2016

Mechanics of Materials

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A Suspended Silicon Single‐Hole Transistor as an Extremely Scaled Gigahertz Nanoelectromechanical Beam Resonator

Zhang

Song

et al. 2020

Advanced Materials

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Recently, silicon (Si)-based single-electron/hole transistor (SET/SHT) showed great promise for next-generation electronics, such as quantum-dot-based quantum computation. [1-3] Leveraging advanced nanofabrication technology developed for very-large-scale integrated circuits, various architecture designs have been proposed to realize controllable single-electron/ hole tunneling. Suspended Si nanobeam SET/SHT, [4] which also acts as a nanoelectromechanical resonator, is one of these new architecture designs. This design not only allows electrical detection of the mechanical vibration using SET/SHT itself, but also provides a platform to explore the possibility of implementing the nanoelectromechanical resonator as a phonon

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High-sensitivity linear piezoresistive transduction for nanomechanical beam resonators

Cited by 50 publications

References 29 publications

Tuning piezoresistive transduction in nanomechanical resonators by geometrical asymmetries

Tuning piezoresistive transduction in nanomechanical resonators by geometrical asymmetries

Thermo-coupled Surface Cauchy–Born theory: An engineering finite element approach to modeling of nanowire thermomechanical response

A Suspended Silicon Single‐Hole Transistor as an Extremely Scaled Gigahertz Nanoelectromechanical Beam Resonator

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