Quasiparticle, charge, and energy conservation in weak‐coupling superconductors

Abstract: The conservation of quasiparticles, electric charge, and energy in weak-couplihg superconductors is discussed and correlated with the interpretation of the quasiparticles as particle and hole excitations. The formulation employed is that of the Bogolyubov-de Gennes equations. In the absence of spin-dependent interactions these equations are written in the form of a time-dependent Schrodinger equation with a two-component wave function and a two-by-two matrix Hamiltonian. Accordingly, the desired conservation l… Show more

“…AS and the associated formation and destruction of Cooper pairs and supercurrents can be calculated from the Time-dependent Bogoliubov-de Gennes Equations (TdBdGE) [18,19,9,23]. They describe the evolution of the spinor quasiparticle (q.p.)…”

“…This equation [18,19,9,23] has a non-vanishing right-hand side if the u l and v l describe quasiparticles that decay exponentially in the superconductor during total Andreev reflection, because their energies are less than the maximum value of ∆. In this case the source equation yields a finite supercurrent j sl .…”

“…While the conversion of a normal current into a supercurrent by electron → hole scattering in the interface between an N and an S region of semi-infinite lengths has been described before [18,19,9], the reverse process has not. Thus, it is the purpose of this paper to analyze the normal-current ←→ supercurrent conversion processes in a superconducting layer of finite length L z between two normal current leads.…”

Dynamics of conversion of supercurrents into normal currents and vice versa

“…AS and the associated formation and destruction of Cooper pairs and supercurrents can be calculated from the Time-dependent Bogoliubov-de Gennes Equations (TdBdGE) [18,19,9,23]. They describe the evolution of the spinor quasiparticle (q.p.)…”

“…This equation [18,19,9,23] has a non-vanishing right-hand side if the u l and v l describe quasiparticles that decay exponentially in the superconductor during total Andreev reflection, because their energies are less than the maximum value of ∆. In this case the source equation yields a finite supercurrent j sl .…”

“…While the conversion of a normal current into a supercurrent by electron → hole scattering in the interface between an N and an S region of semi-infinite lengths has been described before [18,19,9], the reverse process has not. Thus, it is the purpose of this paper to analyze the normal-current ←→ supercurrent conversion processes in a superconducting layer of finite length L z between two normal current leads.…”

Dynamics of conversion of supercurrents into normal currents and vice versa

“…By substituting these definitions into the Bogoliubov-de Gennes equation, we have two conservation laws: [16][17][18] …”

Asymmetric Andreev reflection induced electrical and thermal Hall-like effects in metal/anisotropic superconductor junctions

“…This conversion process is known as Andreev reflection [1]. When the NS junction carries an electrical current, Andreev reflection is accompanied by the conversion of normal current to supercurrent [2,3]. This supercurrent flow modifies the currentvoltage relation in NS and NSN junctions [4][5][6], superconducting wires [7,8], SNS junctions [9], and NS junctions with a supercurrent parallel to the NS interface [10].…”

Excess currents larger than the point contact limit in normal-metal/superconducting junctions