Add to ORKGResonant mechanics of high quality factor (Q) graphene coated silicon nitride devices have been explored using optical and electrical transduction schemes. With the addition of the graphene layer, we retain the desirable mechanical properties of silicon nitride but utilize the electrical and optical properties of graphene to transduce and tune the resonant motion by both optical and electrical means. By positioning the graphene-on-silicon-nitride drums in a tunable optical cavity, we observe position dependent damping and resonant frequency control of the devices due to optical absorption by graphene
Made of only one sheet of carbon atoms, graphene is the thinnest yet strongest material ever exist. ...
Silicon photonics accelerated the advent of complex integrated photonic systems where multiple devic...
There is a recent surge of interest in amplification and detection of tiny motion in the growing fie...
High stress stoichiometric silicon nitride resonators, whose quality factors exceed one million, hav...
Due to their low mass, high quality factor, and good optical properties, silicon nitride (SiN) micro...
This is the final version. Available from the Optical Society of America via the DOI in this record....
Micro- and nano-mechanical resonators with low mass and high vibrational frequency are often studied...
We demonstrate the potential of a graphene capacitor structure on silicon-rich nitride micro-ring re...
We demonstrate high-frequency mechanical resonators in ballistic graphene p-n junctions. Fully suspe...
The achievement of higher frequencies (HF) and the reduction of energy consumption, to improve sens...
Graphene nano-mechanical resonators integrated over waveguides provide a powerful sensing platform b...
We present a scheme for on-chip optical transduction of strain and displacement of graphene-based na...
We present a scheme for on-chip optical transduction of strain and displacement of graphene-based na...
The growing interest in the field of nanomechanical resonators stems from their potential use as hig...
The achievement of higher frequencies (HF) and the reduction of energy consumption, to improve sens...
Made of only one sheet of carbon atoms, graphene is the thinnest yet strongest material ever exist. ...
Silicon photonics accelerated the advent of complex integrated photonic systems where multiple devic...
There is a recent surge of interest in amplification and detection of tiny motion in the growing fie...
High stress stoichiometric silicon nitride resonators, whose quality factors exceed one million, hav...
Due to their low mass, high quality factor, and good optical properties, silicon nitride (SiN) micro...
This is the final version. Available from the Optical Society of America via the DOI in this record....
Micro- and nano-mechanical resonators with low mass and high vibrational frequency are often studied...
We demonstrate the potential of a graphene capacitor structure on silicon-rich nitride micro-ring re...
We demonstrate high-frequency mechanical resonators in ballistic graphene p-n junctions. Fully suspe...
The achievement of higher frequencies (HF) and the reduction of energy consumption, to improve sens...
Graphene nano-mechanical resonators integrated over waveguides provide a powerful sensing platform b...
We present a scheme for on-chip optical transduction of strain and displacement of graphene-based na...
We present a scheme for on-chip optical transduction of strain and displacement of graphene-based na...
The growing interest in the field of nanomechanical resonators stems from their potential use as hig...
The achievement of higher frequencies (HF) and the reduction of energy consumption, to improve sens...
Made of only one sheet of carbon atoms, graphene is the thinnest yet strongest material ever exist. ...
Silicon photonics accelerated the advent of complex integrated photonic systems where multiple devic...
There is a recent surge of interest in amplification and detection of tiny motion in the growing fie...