Add to ORKGThe authors observed resonances from multiple vibrational modes of individual silicon-carbide-based nanomechanical resonators, covering a broad frequency range from several megahertz to over a gigahertz. The devices are actuated thermoelastically in vacuum at room temperature using localized Joule heating in a device-integrated metal loop. Their motion is detected piezoresistively using signal downmixing in a similarly integrated metal piezoresistor. The frequencies and amplitudes of the observed resonant peaks are in good agreement with the results from theoretical modeling and finite-element simulations
We demonstrate a scheme for amplifying nanomechanical motion based on strong parametric interactions...
Nanomechanical experiments on 1-D and 2-D materials are typically conducted at quasi-static strain r...
International audienceWe present a high-sensitivity measurement technique for mechanical nanoresonat...
This thesis describes new ways of operating high-frequency nanomechanical resonators and using them ...
Abstract—This paper presents fabrication, characterization, and modeling of micro/nanoelectromechani...
Over the past decades there has been a great deal of research on developing high frequency micromech...
Parametric resonance and amplification are important in both fundamental physics and technological a...
We report an actuation/detection scheme with a top-down nano-electromechanical system for frequency ...
International audienceThis article presents a comprehensive study and design methodology of co-integ...
Parametric amplification in nanomechanical structures is demonstrated by modulating a purely intrins...
In this work, we demonstrate the integration of piezoelectric actuation means on arrays of nanocanti...
We explore an electrostatic mechanism for tuning the nonlinearity of nanomechanical resonators and i...
Nanoelectromechanical systems provide ultrahigh performance in sensing applications. The sensing per...
Nanomechanical resonators have extremely low masses (~ 10−15 kg) and frequencies from a few megahert...
[[abstract]]Nanomechanical resonators can now be realized that achieve fundamental resonance frequen...
We demonstrate a scheme for amplifying nanomechanical motion based on strong parametric interactions...
Nanomechanical experiments on 1-D and 2-D materials are typically conducted at quasi-static strain r...
International audienceWe present a high-sensitivity measurement technique for mechanical nanoresonat...
This thesis describes new ways of operating high-frequency nanomechanical resonators and using them ...
Abstract—This paper presents fabrication, characterization, and modeling of micro/nanoelectromechani...
Over the past decades there has been a great deal of research on developing high frequency micromech...
Parametric resonance and amplification are important in both fundamental physics and technological a...
We report an actuation/detection scheme with a top-down nano-electromechanical system for frequency ...
International audienceThis article presents a comprehensive study and design methodology of co-integ...
Parametric amplification in nanomechanical structures is demonstrated by modulating a purely intrins...
In this work, we demonstrate the integration of piezoelectric actuation means on arrays of nanocanti...
We explore an electrostatic mechanism for tuning the nonlinearity of nanomechanical resonators and i...
Nanoelectromechanical systems provide ultrahigh performance in sensing applications. The sensing per...
Nanomechanical resonators have extremely low masses (~ 10−15 kg) and frequencies from a few megahert...
[[abstract]]Nanomechanical resonators can now be realized that achieve fundamental resonance frequen...
We demonstrate a scheme for amplifying nanomechanical motion based on strong parametric interactions...
Nanomechanical experiments on 1-D and 2-D materials are typically conducted at quasi-static strain r...
International audienceWe present a high-sensitivity measurement technique for mechanical nanoresonat...