Simulation of the Performance of Graphene FETs With a Semiclassical Model, Including Band-to-Band Tunneling
Academic Article
Publication Date:
2014
Short description:
Simulation of the Performance of Graphene FETs With a Semiclassical Model, Including Band-to-Band Tunneling / Alan, Paussa; Gianluca, Fiori; Palestri, Pierpaolo; Matteo, Geromel; Esseni, David; Giuseppe, Iannaccone; Selmi, Luca. - In: IEEE TRANSACTIONS ON ELECTRON DEVICES. - ISSN 0018-9383. - STAMPA. - 61:5(2014), pp. 1567-1574. [10.1109/TED.2014.2307914]
abstract:
We assess the analog/RF intrinsic performance of graphene FETs (GFETs) through a semiclassical transport model, including local and remote phonon scattering as well as
band-to-band tunneling generation and recombination, validated
by comparison with full quantum results over a wide range
of bias voltages. We found that scaling is expected to improve
the fT , and that scattering plays a role in reducing both
the fT and the transconductance also in sub-100-nm GFETs.
Moreover, we observed a strong degradation of the device performance due to the series resistances and source/drain to channel underlaps.
Iris type:
Articolo su rivista
Keywords:
Band-to-band tunneling (BTBT); Boltzmann transport equation; graphene FET (GFET); graphene monolayer; nonequilibrium Green’s function (NEGF); RF transistors; WKB approximation
List of contributors:
Alan, Paussa; Gianluca, Fiori; Palestri, Pierpaolo; Matteo, Geromel; Esseni, David; Giuseppe, Iannaccone; Selmi, Luca
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