14 research outputs found
Time-dependent quantum transport: causal superfermions, exact fermion-parity protected decay mode, and Pauli exclusion principle for mixed quantum states
We extend the recently developed causal superfermion approach to the
real-time transport theory to time-dependent decay problems.Its usefulness is
illustrated for the Anderson model of a quantum dot with tunneling rates
depending on spin due to the ferromagnetic electrodes and/or spin polarization
of the tunnel junction. We set up a second quantization scheme for density
operators in the Liouville-Fock space constructing causal field superoperators
using the fundamental physical principles of causality/probability conservation
and the fermion-parity superselection (univalence). The time-dependent
perturbation series for the time-evolution is renormalized by explicitly
performing the wide-band limit on the superoperator level. The short and
long-time reservoir correlations are shown to be tightly linked to the
occurrence of causal field destruction and creation superoperators,
respectively. The effective theory takes as a reference a damped local system,
providing an interesting starting point for numerical calculations of memory
kernels in real-time. A remarkable feature of this approach is the natural
appearance of a measurable fermion-parity protected decay mode. It already can
be calculated exactly in the Markovian, infinite temperature limit by leading
order perturbation theory, yet persists unaltered for the finite temperature,
interaction and tunneling spin polarization. Furthermore, we show how a
Liouville-space analog of the Pauli principle directly leads to the exact
result in the noninteracting limit: surprisingly, it is obtained in finite
(second) order renormalized perturbation theory, both for the self-energy as
well as the time-evolution propagator. For this limit we calculate the
time-evolution of the full density operator starting from an arbitrary initial
state on the quantum dot, including spin and pairing coherences and
two-particle correlations.Comment: This version contains the more extensive introduction and the
conclusion, discussing an experimental relevance of the obtained exact result
for the new decay mode. A lot of new references have been added. The more
detailed comparison of the results obtained for the noninteracting case with
the known results has been done. Small typos have been fixe
Fermion-parity duality and energy relaxation in interacting open systems
We study the transient heat current out of a confined electron system into a
weakly coupled electrode in response to a voltage switch. We show that the
decay of the Coulomb interaction energy for this repulsive system exhibits
signatures of electron-electron attraction, and is governed by an
interaction-independent rate. This can only be understood from a general
duality that relates the non-unitary evolution of a quantum system to that of a
dual model with inverted energies. Deriving from the fermion-parity
superselection postulate, this duality applies to a large class of open
systems.Comment: 5 pages + 19 pages of Supplementary Materia
Fermionic superoperators for zero-temperature non-linear transport: real-time perturbation theory and renormalization group for Anderson quantum dots
We study the transport through a strongly interacting Anderson quantum dot at
zero-temperature using the real-time renormalization group (RT-RG) in the
framework of a kinetic equation for the reduced density operator. We further
develop the general finite temperature real-time transport formalism by
introducing field superoperators that obey fermionic statistics. This direct
second quantization in Liouville-Fock space strongly simplifies the
construction of operators and superoperators which transform irreducibly under
the Anderson-model symmetry transformations. The fermionic field superoperators
naturally arise from the univalence (fermion-parity) superselection rule for
the total system. Expressed in these field superoperators, the causal structure
of the perturbation theory for the effective time-evolution
superoperator-kernel becomes explicit. The causal structure also implies the
existence of a fermion-parity protected eigenvector of the exact Liouvillian,
explaining a recently reported result on adiabatic driving [Phys. Rev. B 85,
075301 (2012)] and generalizing it to arbitrary order in the tunnel coupling.
Furthermore, in the WBL the causal representation exponentially reduces the
number of diagrams for the time-evolution kernel. We perform a complete 2-loop
RG analysis at finite voltage and magnetic field, while systematically
accounting for the dependence on both the quantum dot and reservoir
frequencies. Using the second quantization in Liouville-space and symmetry
restrictions we obtain analytical RT-RG equations with an efficient numerical
solution and we extensively study the model parameter space, excluding the
Kondo regime. The incorporated renormalization effects result in an enhancement
of the inelastic cotunneling peak. Moreover, we find a tunnel-induced
non-linearity of the stability diagrams at finite voltage, both in the SET and
ICT regime.Comment: With respect to the version of 13.07.2012: Corrected typos. Fig.1 was
corrected. Right scales on Fig.6b were set. English grammatic improved. One
reference adde
On the instability of a homogeneous state of a weakly interacting Bose gas under external cooling
The behavior of a weakly interacting Bose gas with a finite particle lifetime has been studied in the framework of hydrodynamic equations under the conditions of a constant mass and energy inflow in the presence of external cooling. A spatially homogeneous state of such a gas is shown to be unstable with respect to the formation of an inhomogeneous density structure. A possible connection of the present results with experiments [3, 4] is discussed
Condensate Formation and Vortex Generation in Bose Gas upon Cooling
The mechanism of transition of a Bose gas to the superfluid state via thermal fluctuations under the condition of external cooling at a temperature above the transition point is considered. The probability of formation of such critical fluctuations (instantons) is calculated; it is found that this probability increases as the system approaches the transition temperature. It is shown that the evolution of an individual instanton is impossible without the formation of vortices in its superfluid part. (C) 2004 MAIK "Nauka / Interperiodica"