Fermion-parity duality and energy relaxation in interacting open systems

Schulenborg, Jens; Saptsov, R. B.; Haupt, Federica; Splettstoesser, Janine; Wegewijs, M. R.

doi:10.1103/physrevb.93.081411

Cited by 33 publications

(186 citation statements)

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“…The surprising result of Ref. is that such a physical connection between modes and amplitude covectors indeed turns out to exist for a large class of fermionic systems. Namely, this applies to systems that (i) evolve in time according to a Hamiltonian of the form –, (ii) contain noninteracting electronic leads r that are initially uncorrelated with the subsystem, and each in equilibrium (temperatures

T_{r}

, electrochemical potentials

μ_{r}

), and (iii) have tunneling frequencies

Γ_{italicrl σ} false(ω false) = 2 π \sum_{k, n} δ false(ε_{italicrn σ} false(k false) - ω false) false| τ_{italicrnl σ} false(k false) |^{2} \to Γ_{italicrl σ}

that are energy

false(ω false)

‐independent (wideband limit).…”

Section: Duality Relation For Open Electronic Systemsmentioning

confidence: 99%

“…To formulate the duality clearly, we need some more suitable notation. Realizing that the set of operators acting on the Hilbert space of the open system forms a vector space –the so‐called Liouville space –we denote an operator x as a “ket” vector

| x) = x

. Via the Hilbert–Schmidt scalar product, we can let a vector

| x)

act on another vector

| •)

to yield a scalar number: with

•

denoting an operator argument, we define a “bra” or covector

(x | • = normalTr false[x^{†} • false]

.…”

Section: Duality Relation For Open Electronic Systemsmentioning

confidence: 99%

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Relaxation of quantum dots in a magnetic field at finite bias – Charge, spin, and heat currents

Vanherck

Schulenborg

Saptsov

et al. 2017

Physica Status Solidi (b)

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We perform a detailed study of the effect of finite bias and magnetic field on the tunneling‐induced decay of the state of a quantum dot by applying a recently discovered general duality [Phys. Rev. B 93, 81411 (2016)]. This duality provides deep physical insight into the decay dynamics of electronic open quantum systems with strong Coulomb interaction. It associates the amplitudes of decay eigenmodes of the actual system to the eigenmodes of a so‐called dual system with attractive interaction. Thereby, it predicts many surprising features in the transient transport and its dependence on experimental control parameters: the attractive interaction of the dual model shows up as sharp features in the amplitudes of measurable time‐dependent currents through the actual repulsive system. In particular, for interacting quantum dots, the time‐dependent heat current exhibits a decay mode that dissipates the interaction energy and that is tied to the fermion parity of the system. We show that its decay amplitude has an unexpected gate‐voltage dependence that is robust up to sizable bias voltages and then bifurcates, reflecting that the Coulomb blockade is lifted in the dual system. Furthermore, combining our duality relation with the known Iche‐duality, we derive new symmetry properties of the decay rates as a function of magnetic field and gate voltage. Finally, we quantify charge‐ and spin‐mode mixing due to the magnetic field using a single mixing parameter.

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T_{r}

, electrochemical potentials

μ_{r}

), and (iii) have tunneling frequencies

Γ_{italicrl σ} false(ω false) = 2 π \sum_{k, n} δ false(ε_{italicrn σ} false(k false) - ω false) false| τ_{italicrnl σ} false(k false) |^{2} \to Γ_{italicrl σ}

that are energy

false(ω false)

‐independent (wideband limit).…”

Section: Duality Relation For Open Electronic Systemsmentioning

confidence: 99%

| x) = x

. Via the Hilbert–Schmidt scalar product, we can let a vector

| x)

act on another vector

| •)

to yield a scalar number: with

•

denoting an operator argument, we define a “bra” or covector

(x | • = normalTr false[x^{†} • false]

.…”

Section: Duality Relation For Open Electronic Systemsmentioning

confidence: 99%

Relaxation of quantum dots in a magnetic field at finite bias – Charge, spin, and heat currents

Vanherck

Schulenborg

Saptsov

et al. 2017

Physica Status Solidi (b)

View full text Add to dashboard Cite

show abstract

“…[370] treats interacting systems with adiabatic driving. One extremely recent work used similar methods for non-equilibrium propagators in time (rather than energy) on the Keldysh contour [357], it claims that one can use a method known as real-time transport theory [371][372][373][374][375][376][377][378] to prove the second law of thermodynamics, and the fluctuation theorems in sections 8.10.2-8.10.5, for an arbitrary interacting quantum system with or without time-dependent driving. All these works raise a number questions, and we feel it is much too soon to write a definitive review of these methods.…”

Section: Non-equilibrium Green's Functions and Real-time Transport Thmentioning

confidence: 99%

Fundamental aspects of steady-state conversion of heat to work at the nanoscale

et al. 2017

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In recent years, the study of heat to work conversion has been re-invigorated by nanotechnology. Steady-state devices do this conversion without any macroscopic moving parts, through steady-state flows of microscopic particles such as electrons, photons, phonons, etc. This review aims to introduce some of the theories used to describe these steady-state flows in a variety of mesoscopic or nanoscale systems. These theories are introduced in the context of idealized machines which convert heat into electrical power (heat-engines) or convert electrical power into a heat flow (refrigerators). In this sense, the machines could be categorized as thermoelectrics, although this should be understood to include photovoltaics when the heat source is the sun. As quantum mechanics is important for most such machines, they fall into the field of quantum thermodynamics. In many cases, the machines we consider have few degrees of freedom, however the reservoirs of heat and work that they interact with are assumed to be macroscopic. This review discusses different theories which can take into account different aspects of mesoscopic and nanoscale physics, such as coherent quantum transport, magnetic-field induced effects (including topological ones such as the quantum Hall effect), and single electron charging effects. It discusses the efficiency of thermoelectric conversion, and the thermoelectric figure of merit. More specifically, the theories presented are (i) linear response theory with or without magnetic fields, (ii) Landauer scattering theory in the linear response regime and far from equilibrium, (iii) Green-Kubo formula for strongly interacting systems within the linear response regime, (iv) rate equation analysis for small quantum machines with or without interaction effects, (v) stochastic thermodynamic for fluctuating small systems. In all cases, we place particular emphasis on the fundamental questions about the bounds on ideal machines. Can magnetic-fields change the bounds on power or efficiency? What is the relationship between quantum theories of transport and the laws of thermodynamics? Does quantum mechanics place fundamental bounds on heat to work conversion which are absent in the thermodynamics of classical systems?

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“…The magnetic field B is initially added for our comparison with the FCS approach in Appendix I. We later focus on zero magnetic field results [68,69,75,98], and make use of the supplemental information to [156] where more details can be found.…”

Section: Appendix D: Interaction-induced Pumping Through a Quantum Dotmentioning

confidence: 99%

“…Therefore, driving of L /¯ and R /¯ effectively amounts to single parameter driving. using notation borrowed from [156] the pumping response covector (84) is obtained as N is the fermion-parity operator which plays a special role [156].…”

Section: =¯mentioning

confidence: 99%

Gauge freedom in observables and Landsberg's nonadiabatic geometric phase: Pumping spectroscopy of interacting open quantum systems

2017

Self Cite

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We set up a general density-operator approach to geometric steady-state pumping through slowly driven open quantum systems. This approach applies to strongly interacting systems that are weakly coupled to multiple reservoirs at high temperature, illustrated by an Anderson quantum dot. Pumping gives rise to a nonadiabatic geometric phase that can be described by a framework originally developed for classical dissipative systems by Landsberg. This geometric phase is accumulated by the transported observable (charge, spin, energy) and not by the quantum state. It thus differs radically from the adiabatic Berry-Simon phase, even when generalizing it to mixed states, following Sarandy and Lidar.As a key feature, our geometric formulation of pumping stays close to a direct physical intuition (i) by tying gauge transformations to calibration of the meter registering the transported observable and (ii) by deriving a geometric connection from a driving-frequency expansion of the current. Furthermore, our approach provides a systematic and efficient way to compute the geometric pumping of various observables, including charge, spin, energy and heat. These insights seem to be generalizable beyond the present paper's working assumptions (e.g., Born-Markov limit) to more general opensystem evolutions involving memory and strong-coupling effects due to low temperature reservoirs as well.Our geometric curvature formula reveals a general experimental scheme for performing geometric transport spectroscopy that enhances standard nonlinear spectroscopies based on measurements for static parameters. We indicate measurement strategies for separating the useful geometric pumping contribution to transport from nongeometric effects.A large part of the paper is devoted to an explicit comparison with the Sinitsyn-Nemenmann fullcounting statistics (FCS) approach to geometric pumping, restricting attention to the first moments of the pumped observable. Covering all key aspects, gauge freedom, pumping connection, curvature, and gap condition, we argue that our approach is physically more transparent and, importantly, simpler for practical calculations. In particular, this comparison allows us to clarify how in the FCS approach an "adiabatic" approximation leads to a manifestly nonadiabatic result involving a finite retardation time of the response to parameter driving. PACS numbers: 73.63.Kv, 05.60.Gg, 72.10.Bg 03.65.VfTABLE I. Comparison of geometric density-operator approaches relevant to this paper. Approach Prior works Present work (I) Adiabatic state Adiabatic mixed-state geometric phase 37,38 Zero geometric phase for adiabatic steady-state [Sec. III A] evolution (ASE) Mixed-state adiabatic-response correction 37,38 Zero geometric phase for nonadiabatic state [Sec. III A] Gauge freedom related to eigenvector rescaling 37,38 Restriction of gauge freedom by normalization and hermiticity [Sec. III A] (II) Full counting Geometric part of generating function 40,44,72-75 Restriction of gauge freedom by real-valuedness observable [Sec. V C 3] ...

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Fermion-parity duality and energy relaxation in interacting open systems

Cited by 33 publications

References 50 publications

Relaxation of quantum dots in a magnetic field at finite bias – Charge, spin, and heat currents

Relaxation of quantum dots in a magnetic field at finite bias – Charge, spin, and heat currents

Fundamental aspects of steady-state conversion of heat to work at the nanoscale

Gauge freedom in observables and Landsberg's nonadiabatic geometric phase: Pumping spectroscopy of interacting open quantum systems

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