Title :
Graphene-Based Ambipolar RF Mixers
Author :
Wang, Han ; Hsu, Allen ; Wu, Justin ; Kong, Jing ; Palacios, Tomas
Author_Institution :
Microsyst. Technol. Labs., Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
The combination of the unique properties of graphene with new device concepts and nanotechnology can overcome some of the main limitations of traditional electronics in terms of maximum frequency, linearity, and power dissipation. In this letter, we demonstrate the use of the ambipolar-transport properties of graphene for the fabrication of a new kind of RF mixer device. Due to the symmetrical ambipolar conduction in graphene, graphene-based mixers can effectively suppress odd-order intermodulations and lead to lower spurious emissions in the circuit. The mixer operation was demonstrated at a frequency of 10 MHz using graphene grown by chemical vapor deposition on a Ni film and then transferred to an insulating substrate. The maximum operating frequency was limited by the device geometry and the measurement setup, and a high-quality factor was observed with a third-order intercept point of +13.8 dBm.
Keywords :
chemical vapour deposition; graphene; microwave mixers; nickel; Ni; ambipolar-transport properties; chemical vapor deposition; device geometry; frequency 10 MHz; graphene-based ambipolar RF mixers; high-quality factor; insulating substrate; nanotechnology; nickel film; odd-order intermodulation suppression; spurious emissions; symmetrical ambipolar conduction; third-order intercept point; Chemical vapor deposition; Circuits; Fabrication; Geometry; Insulation; Linearity; Nanotechnology; Power dissipation; Radio frequency; Substrates; Ambipolar conduction; chemical vapor deposition (CVD) graphene; graphene field-effect transistors (GFET); mixers;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2010.2052017
