Abstract
We propose Graphene Klein tunnel transistors (GKTFET) as a way to enforce current saturation while maintaining large mobility for high speed radio frequency (RF) applications. The GKTFET consists of a sequence of angled graphene p-n junctions (GPNJs). Klein tunneling creates a collimation of electrons across each GPNJ, so that the lack of substantial overlap between transmission lobes across successive junctions creates a gate-tunable transport gap without significantly compromising the on-current. Electron scattering at the device edge tends to bleed parasitic states into the gap, but the resulting pseudogap is still sufficient to create a saturated output (ID–VD) characteristic and a high output resistance. The modulated density of states generates a higher transconductance (gm) and unity current gain cut-off frequency (fT) than GFETs. More significantly the high output resistance makes the unity power gain cut-off frequency (fmax) of GKTFETs considerably larger than GFETs, making analog GKTFET potentially useful for RF electronics. Our estimation shows the fT/fmax of a GKTFET with 1 μm channel reaches 33 GHz/17 GHz, and scale up to 350 GHz/53 GHz for 100 nm channel (assuming a single, scalable trapezoidal gate). The fmax of a GKTFET is 10 times higher than a GFET with the same channel length.
Highlights
Graphene-based devices have long promised exciting applications, from interconnects and transparent electrodes to gas sensing
We have shown that a 1 μm long GKTFET shows much better rout and cutoff frequencies fmax than GFETs due to the transmission gap engineered in pristine graphene using gate geometry
This device operates by geometry engineering of a gate-tunable transport gap in pristine graphene, using the physics of Klein tunneling
Summary
Graphene-based devices have long promised exciting applications, from interconnects and transparent electrodes to gas sensing. Their gaplessness compromises our ability to gate these devices as an efficient electronic switch. Efforts to improve the fmax of GFETs have focused on reducing the input resistance and introducing current saturation. Scattering process in a long graphene channel can introduce natural current saturation[14]. Those band gap opening mechanisms significantly reduce the carrier mobility due to the distorted bandstructure or carrier scattering events[15]. Gray region corresponds to the energy range of the transmission gap in the ON state. (f) Equivalent small signal circuit
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