Nonequilibrium Kondo effect in a graphene-coupled quantum dot in the presence of a magnetic field

Abstract: Quantum dots connected to larger systems containing a continuum of states like charge reservoirs allow the theoretical study of many-body effects such as the Coulomb blockade and the Kondo effect. Here, we analyze the nonequilibrium Kondo effect and transport phenomena in a quantum dot coupled to pure monolayer graphene electrodes under external magnetic fields for finite on-site Coulomb interaction. The system is described by the pseudogap Anderson Hamiltonian. We use the equation of motion technique to deter… Show more

“…The dressed lesser (greater) Green’s function is calculated by employing the Keldysh equation with the use of corresponding lesser (greater) self-energy . Thus, the current given in relation ( 7 ), at finite temperature, reads [ 60 ] The dressed retarded Green’s functions of the QD, and , in Equation ( 11 ) are calculated by employing the equation of motion technique [ 60 , 72 ]: with . Note that if , the retarded Green’s functions given by Equation ( 12 ) reduce to the results of [ 56 ].…”

Phonon-Assisted Tunneling through Quantum Dot Systems Connected to Majorana Bound States

“…The dressed lesser (greater) Green’s function is calculated by employing the Keldysh equation with the use of corresponding lesser (greater) self-energy . Thus, the current given in relation ( 7 ), at finite temperature, reads [ 60 ] The dressed retarded Green’s functions of the QD, and , in Equation ( 11 ) are calculated by employing the equation of motion technique [ 60 , 72 ]: with . Note that if , the retarded Green’s functions given by Equation ( 12 ) reduce to the results of [ 56 ].…”

Phonon-Assisted Tunneling through Quantum Dot Systems Connected to Majorana Bound States

“…In this section, we calculate the dot retarded Green's functions for arbitrary values of ε M , λ 1 and λ 2 by using the EOM technique. In order to do this, we define the retarded Green's function for fermionic operators A and B as A(t)|B(0) r t = −iθ(t) {A(t), B(0)} where θ(t) is the Heaviside function [141][142][143]. The Fourier transform for A(t)|B(0) r t is given by A|B r ε .…”

“…The Fourier transform for A(t)|B(0) r t is given by A|B r ε . We write down the EOM for the retarded Green's function in energy space as ε + A|B r ε + [ Hel , A]|B r ε = {A, B} where ε + = ε + iδ with δ, a positive infinitesimal [141][142][143]. We introduce the electron-electron and electron-hole retarded Green's functions for the dot as Gr The EOM for Gr d11 (ε) is expressed as…”

Quantum transport through a quantum dot side-coupled to a Majorana bound state pair in the presence of electron-phonon interaction

Decoherence of a Hadamard basis state in three-spin system: The case of tunnel-couplings to semi-infinite graphene electrodes with armchair edges