Signature of the transition to a bound state in thermoelectric quantum transport

Jussiau, Étienne; Hasegawa, Mayumi; Whitney, Robert S.

doi:10.1103/physrevb.100.115411

Cited by 16 publications

(18 citation statements)

References 56 publications

(158 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…which has strict finite support. It should be noted that whereas non-vanishing spectral densities (Schaller et al, 2009;Topp et al, 2015) can be used to model non-Markovian effects , a spectral density with strict finite support can even lead to phenomena like bound states that may persist even in the long-term limit (Jussiau et al, 2019). To invert the Laplace transform, we can then analytically calculate expressions like…”

Section: J Connection With Exactly Solvable Systemsmentioning

confidence: 99%

Non-equilibrium boundary driven quantum systems: models, methods and properties

Landi¹,

Poletti²,

Schaller³

2021

Preprint

View full text Add to dashboard Cite

Recent years have seen tremendous progress in the theoretical understanding of quantum systems driven dissipatively by coupling them to different baths at their edges. This was possible because of the concurrent advances in the models used to represent these systems, the methods employed, and the analysis of the emerging phenomenology. Here we aim to give a comprehensive review of these three integrated research directions. We first provide an overarching view of the models of boundary driven open quantum systems, both in the weak and strong coupling regimes. This is followed by a review of state-of-the-art analytical and numerical methods, both exact, perturbative and approximate. Finally, we discuss the transport properties of some paradigmatic one-dimensional chains, with an emphasis on disordered and quasiperiodic systems, the emergence of rectification and negative differential conductance, and the role of phase transitions.

show abstract

Section: J Connection With Exactly Solvable Systemsmentioning

confidence: 99%

Non-equilibrium boundary driven quantum systems: models, methods and properties

Landi¹,

Poletti²,

Schaller³

2021

Preprint

View full text Add to dashboard Cite

show abstract

“…To derive these expressions we have to assume the existence of a nonequilibrium steady state and this is related to the existence of bound states (discrete energy levels) in the spectrum of the entire coupled system of the superconducting wire and the baths (non-interacting normal electrons). The role of bound states on the existence of steady states is known for normal systems 24,[28][29][30] and has recently been investigated for the case of superconductors in Ref. [22].…”

Section: Discussionmentioning

confidence: 99%

“…Using Eqs. (29,30,33) and the correlation properties of the noise terms we finally obtain the following expression for current:…”

Section: A Steady State Currentmentioning

confidence: 99%

Transport in spinless superconducting wires

Bhat,

Dhar

2020

Preprint

View full text Add to dashboard Cite

We consider electron transport in a model of a spinless superconductor described by a Kitaev type lattice Hamiltonian where the electron interactions are modelled through a superconducting pairing term. The superconductor is sandwiched between two normal metals kept at different temperatures and chemical potentials and are themselves modelled as non-interacting spinless fermions. For this set-up we compute the exact steady state properties of the system using the quantum Langevin equation approach. The closed form exact expressions for current and other two-point correlations are obtained in the Landauer-type forms and involve two nonequilibrium Green's functions. We then discuss a numerical approach where we construct the time-evolution of the two point correlators of the system from the eigenspectrum of the complete quadratic Hamiltonian describing the system and leads. By starting from an initial state corresponding to the leads in thermal equilibrium and the system in an arbitrary state, the long time solution for the correlations, before recurrence times, gives us steady state properties. We use this independent numerical method for verifying the results of the exact solution and to comment on the role of bound states. Our results are quite general and applicable to arbitrary lattices in any dimensions.

show abstract

“…that allows perfect energy transfers in the transmission window [ω min , ω max ] and blocks transfers anywhere else, one may reach a situation yielding a finite matter current I M with negligible noise S M (note that we only discuss the contributions rising linearly in time and thereby neglect features such as bound states 58 or any constant finite contributions) that saturates the FTUR bound (11). In the current and noise integrals (2), the integration boundary will then be limited to the interval [ω min , ω max ] for a rectangular transmission function.…”

Section: Motivation: Minimizing Uncertaintymentioning

confidence: 99%

Broadband frequency filters with quantum dot chains

Ehrlich,

Schaller

2021

Preprint

View full text Add to dashboard Cite

Two-terminal electronic transport systems with a rectangular transmission can violate standard thermodynamic uncertainty relations. This is possible beyond the linear response regime and for parameters that are not accessible with rate equations obeying detailed-balance. Looser bounds originating from fluctuation theorem symmetries alone remain respected. We demonstrate that optimal finite-sized quantum dot chains can implement rectangular transmission functions with high accuracy and discuss the resulting violations of standard thermodynamic uncertainty relations as well as heat engine performance.

show abstract

Signature of the transition to a bound state in thermoelectric quantum transport

Cited by 16 publications

References 56 publications

Non-equilibrium boundary driven quantum systems: models, methods and properties

Non-equilibrium boundary driven quantum systems: models, methods and properties

Transport in spinless superconducting wires

Broadband frequency filters with quantum dot chains

Contact Info

Product

Resources

About