TY - JOUR
T1 - Scalable tight-binding model for graphene
AU - Liu, Ming Hao
AU - Rickhaus, Peter
AU - Makk, Péter
AU - Tóvári, Endre
AU - Maurand, Romain
AU - Tkatschenko, Fedor
AU - Weiss, Markus
AU - Schönenberger, Christian
AU - Richter, Klaus
N1 - Publisher Copyright:
© 2015 American Physical Society.
PY - 2015/1/22
Y1 - 2015/1/22
N2 - Artificial graphene consisting of honeycomb lattices other than the atomic layer of carbon has been shown to exhibit electronic properties similar to real graphene. Here, we reverse the argument to show that transport properties of real graphene can be captured by simulations using "theoretical artificial graphene." To prove this, we first derive a simple condition, along with its restrictions, to achieve band structure invariance for a scalable graphene lattice. We then present transport measurements for an ultraclean suspended single-layer graphene pn junction device, where ballistic transport features from complex Fabry-Pérot interference (at zero magnetic field) to the quantum Hall effect (at unusually low field) are observed and are well reproduced by transport simulations based on properly scaled single-particle tight-binding models. Our findings indicate that transport simulations for graphene can be efficiently performed with a strongly reduced number of atomic sites, allowing for reliable predictions for electric properties of complex graphene devices. We demonstrate the capability of the model by applying it to predict so-far unexplored gate-defined conductance quantization in single-layer graphene.
AB - Artificial graphene consisting of honeycomb lattices other than the atomic layer of carbon has been shown to exhibit electronic properties similar to real graphene. Here, we reverse the argument to show that transport properties of real graphene can be captured by simulations using "theoretical artificial graphene." To prove this, we first derive a simple condition, along with its restrictions, to achieve band structure invariance for a scalable graphene lattice. We then present transport measurements for an ultraclean suspended single-layer graphene pn junction device, where ballistic transport features from complex Fabry-Pérot interference (at zero magnetic field) to the quantum Hall effect (at unusually low field) are observed and are well reproduced by transport simulations based on properly scaled single-particle tight-binding models. Our findings indicate that transport simulations for graphene can be efficiently performed with a strongly reduced number of atomic sites, allowing for reliable predictions for electric properties of complex graphene devices. We demonstrate the capability of the model by applying it to predict so-far unexplored gate-defined conductance quantization in single-layer graphene.
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U2 - 10.1103/PhysRevLett.114.036601
DO - 10.1103/PhysRevLett.114.036601
M3 - Article
AN - SCOPUS:84921514669
SN - 0031-9007
VL - 114
JO - Physical review letters
JF - Physical review letters
IS - 3
M1 - 036601
ER -