Quantum transport at the Dirac point: Mapping out the minimum conductivity from pristine to disordered graphene

Abstract We theoretically express quantum transport at Dirac points via graphene quantum billiard as a non-magnetic material to connect metallic leads. Our results indicate that the quantum billiard of graphene is similar to a resonant tunnelling device. The centerpiece size and the Fermi energy of the graphene quantum billiard play an important role in the resonant tunnelling. In graphene, change of carrier density can affect plasmon polaritons. At the Dirac point, the conductivity of graphene depends on the geometry, so that the conduction of the evanescent modes is close to the theoretical value of 4e2/πh (where Planck's constant and the electron charge are denoted by h and e, respectively.). This transport property can be used to justify chaotic quantum systems and ballistic transistors. Our theoretical results demonstrate that the local density of state of the graphene sheet for EL = ER = 0 is larger than EL = ER = t (where EL (ER) is onsite energy of the left (right) metallic lead) unlike the current obtained from the calculations.

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Quantum transport at Dirac point enables molecularly doped graphene for terahertz heterodyne astronomy (Conference Presentation)

Optical Sensing, Imaging, and Photon Counting: From X-Rays to THz 2019 ◽

10.1117/12.2530944 ◽

2019 ◽

Author(s):

Samuel Lara-Avila ◽

Andrey Danilov ◽

Dmitry Golubev ◽

Hans He ◽

Kyung Ho Kim ◽

...

Keyword(s):

Quantum Transport ◽

Dirac Point ◽

Doped Graphene

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Single-band quantum transport study of resonant tunneling diodes based on silicene nanoribbons

2020 43rd International Convention on Information, Communication and Electronic Technology (MIPRO) ◽

10.23919/mipro48935.2020.9245394 ◽

2020 ◽

Author(s):

M. Mihaljevic ◽

M. Siric ◽

M. Poljak

Keyword(s):

Quantum Transport ◽

Resonant Tunneling ◽

Single Band ◽

Resonant Tunneling Diodes ◽

Tunneling Diodes ◽

Transport Study ◽

Silicene Nanoribbons

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Quantum Transport in Si:P δ-Layer Wires

2020 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD) ◽

10.23919/sispad49475.2020.9241610 ◽

2020 ◽

Author(s):

Juan P. Mendez ◽

Denis Mamaluy ◽

Xujiao Gao ◽

Evan M. Anderson ◽

DeAnna M. Campbell ◽

...

Keyword(s):

Quantum Transport

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Nonequilibrium Green’s Functions

10.1093/oso/9780198797241.003.0007 ◽

2018 ◽

Author(s):

Klaus Morawetz

Keyword(s):

Green’S Function ◽

Quantum Transport ◽

Green's Function ◽

Green's Functions ◽

Green’S Functions ◽

Equation Of Motion ◽

Diagrammatic Technique ◽

Initial Correlations ◽

Nonequilibrium Green’S Functions ◽

Nonequilibrium Green's Functions

The method of the equation of motion is used to derive the Martin–Schwinger hierarchy for the nonequilibrium Green’s functions. The formal closure of the hierarchy is reached by using the selfenergy which provides a recipe for how to construct selfenergies from approximations of the two-particle Green’s function. The Langreth–Wilkins rules for a diagrammatic technique are shown to be equivalent to the weakening of initial correlations. The quantum transport equations are derived in the general form of Kadanoff and Baym equations. The information contained in the Green’s function is discussed. In equilibrium this leads to the Matsubara diagrammatic technique.

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