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Abstract
Graphene is a promising candidate for optoelectronic applications. In this report, a double gated bilayer graphene FET has been made using a combination of electrostatic and electrolytic gating in order to form an abrupt p-n junction. The presence of two Dirac peaks in the gating curve of the fabricated device confirms the formation of a p-n junction. At low temperatures, when the electrolyte is frozen intentionally, the photovoltage exhibits a six-fold pattern indicative of the hot electron induced photothermoelectric effect that has also been seen in graphene p-n junctions made using metallic gates. We have observed that the photovoltage increases with decreasing temperature indicating a dominant role of supercollision scattering. Our technique can also be extended to other 2D materials and to finer features that will lead to p-n junctions which span a large area, like a superlattice, that can generate a larger photoresponse. Our work creating abrupt p-n junctions is distinct from previous works that use a source–drain bias voltage with a single ionic gate creating a spatially graded p-n junction.
Highlights
Graphene[1] has unique optical[2,3,4] and electronic[5] properties which has made it a promising material for optoelectronic devices such as photodetectors
Electrolytic gating has been used for tuning the carrier density in various semiconductors such as organic polymers[9], carbon nanotubes[10], and superconductors[11, 12]
We demonstrate the formation of a p-n junction in graphene using a combination of electrostatic and electrolytic gating at zero bias
Summary
Graphene[1] has unique optical[2,3,4] and electronic[5] properties which has made it a promising material for optoelectronic devices such as photodetectors. Graphene p-n junctions have previously been created using metallic gates and with electrolytic gating by putting ionic liquid drop on millimetre sized CVD graphene[26] and by applying a drain-source bias comparable with the gate voltage[27].
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