Title :
Conductance Asymmetry of Graphene p-n Junction
Author :
Low, Tony ; Hong, Seokmin ; Appenzeller, Joerg ; Datta, Supriyo ; Lundstrom, Mark S.
Author_Institution :
Sch. of Electr. & Comput. Eng., Purdue Univ., West Lafayette, IN
fDate :
6/1/2009 12:00:00 AM
Abstract :
We use the nonequilibrium Green function method in the ballistic limit to provide a quantitative description of the conductance of graphene p-n junctions - an important building block for graphene electronics devices. In this paper, recent experiments on graphene junctions are explained by a ballistic transport model, but only if the finite junction transition width D w is accounted for. In particular, the experimentally observed anomalous increase in the resistance asymmetry between n-n and n-p junctions under low source/drain charge density conditions is also quantitatively captured by our model. In light of the requirement for sharp junctions in applications such as electron focusing, we also examine the p-n junction conductance in the regime where D w is small and find that wave-function mismatch (so-called pseudospin) plays a major role in sharp p-n junctions.
Keywords :
Green´s function methods; ballistic transport; electrical conductivity; graphene; p-n junctions; wave functions; C; ballistic transport model; conductance asymmetry; graphene p-n junction; low source/drain charge density; nonequilibrium Green function method; wave-function mismatch; Ballistic transport; Band pass filters; Computer networks; Electrons; Green function; Lattices; Nanotechnology; P-n junctions; Photonic band gap; Tunneling; Conductance asymmetry; graphene; non-equilibrium green function; p-n junction;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2009.2017646
