Add to ORKGWe demonstrate that the low-frequency resistance uctuations, or noise, in bilayer graphene is strongly connected to its band structure, and displays a minimum when the gap between the conduction and valence band is zero. Using double-gated bilayer graphene devices we have tuned the zero gap and charge neutrality points independently, which oers a versatile mechanism to investigate the low-energy band structure, charge localization and screening properties of bilayer graphene
We present a novel and comprehensive model of 1/f noise in nanoscale graphene devices that accounts ...
The importance of controlling both the charge carrier density and the band gap of a semiconductor ca...
We present low-frequency electrical resistance fluctuations, or noise, in graphene-based field-effec...
We demonstrate that the low-frequency resistance uctuations, or noise, in bilayer graphene is strong...
We demonstrate that the low-frequency resistance fluctuations, or noise, in bilayer graphene are str...
We demonstrate that the low-frequency resistance fluctuations, or noise, in bilayer graphene are str...
We present a low-frequency electrical noise measurement in graphene based field effect transistors. ...
We present a low-frequency electrical noise measurement in graphene based field effect transistors. ...
We present a low‐frequency electrical noise measurement in graphene based field effect transistors. ...
Bilayer graphene (BLG), endowed with its electrostatically tunable band gap, plays a special role in...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
Dataset for the Publication "Transport spectroscopy of ultraclean tunable band gaps in bilayer graph...
We present a novel and comprehensive model of 1/f noise in nanoscale graphene devices that accounts ...
The importance of controlling both the charge carrier density and the band gap of a semiconductor ca...
We present low-frequency electrical resistance fluctuations, or noise, in graphene-based field-effec...
We demonstrate that the low-frequency resistance uctuations, or noise, in bilayer graphene is strong...
We demonstrate that the low-frequency resistance fluctuations, or noise, in bilayer graphene are str...
We demonstrate that the low-frequency resistance fluctuations, or noise, in bilayer graphene are str...
We present a low-frequency electrical noise measurement in graphene based field effect transistors. ...
We present a low-frequency electrical noise measurement in graphene based field effect transistors. ...
We present a low‐frequency electrical noise measurement in graphene based field effect transistors. ...
Bilayer graphene (BLG), endowed with its electrostatically tunable band gap, plays a special role in...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
A distinctive feature of single-layer graphene is the linearly dispersive energy bands, which in the...
Dataset for the Publication "Transport spectroscopy of ultraclean tunable band gaps in bilayer graph...
We present a novel and comprehensive model of 1/f noise in nanoscale graphene devices that accounts ...
The importance of controlling both the charge carrier density and the band gap of a semiconductor ca...
We present low-frequency electrical resistance fluctuations, or noise, in graphene-based field-effec...