1,083 research outputs found
Magnon transport and spin current switching through quantum dots
We study the nonequilibrium spin current through a quantum dot consisting of
two localized spin-1/2 coupled to two ferromagnetic insulators. The influence
of an intra-dot magnetic field and exchange coupling, different dot-reservoir
coupling configurations, and the influence of magnon chemical potential
differences vs. magnetic field gradients onto the spin current are examined. We
discuss various spin switching mechanisms and find that, in contrast to
electronic transport, the spin current is very sensitive to the specific
coupling configuration and band edges. In particular, we identify 1- and
2-magnon transport processes which can lead to resonances and antiresonances
for the spin current.Comment: 10 pages, 15 figure
Influence of nano-mechanical properties on single electron tunneling: A vibrating Single-Electron Transistor
We describe single electron tunneling through molecular structures under the
influence of nano-mechanical excitations. We develop a full quantum mechanical
model, which includes charging effects and dissipation, and apply it to the
vibrating C single electron transistor experiment by Park {\em et al.}
{[Nature {\bf 407}, 57 (2000)].} We find good agreement and argue vibrations to
be essential to molecular electronic systems. We propose a mechanism to realize
negative differential conductance using local bosonic excitations.Comment: 7 pages, 6 figure
Spin quantum tunneling in single molecular magnets: fingerprints in transport spectroscopy of current and noise
We demonstrate that transport spectroscopy of single molecular magnets shows
signatures of quantum tunneling at low temperatures. We find current and noise
oscillations as function of bias voltage due to a weak violation of spin
selection rules by quantum tunneling processes. The interplay with Boltzmann
suppression factors leads to fake resonances with temperature-dependent
position which do not correspond to any charge excitation energy. Furthermore,
we find that quantum tunneling can completely suppress transport if the
easy-plane anisotropy has a high symmetry.Comment: 4 pages, 3 figure
Non-Linear Transport through a Molecular Nanojunction
We present a simple model of electrical transport through a
metal-molecule-metal nanojunction that includes charging effects as well as
aspects of the electronic structure of the molecule. The interplay of a large
charging energy and an asymmetry of the metal-molecule coupling can lead to
various effects in non-linear electrical transport. In particular, strong
negative differential conductance is observed under certain conditions.Comment: 7 pages, 5 figures, accepted by Europhys. Let
Quantum tunneling induced Kondo effect in single molecular magnets
We consider transport through a single-molecule magnet strongly coupled to
metallic electrodes. We demonstrate that for half-integer spin of the molecule
electron- and spin-tunneling \emph{cooperate} to produce both quantum tunneling
of the magnetic moment and a Kondo effect in the linear conductance. The Kondo
temperature depends sensitively on the ratio of the transverse and easy-axis
anisotropies in a non-monotonic way. The magnetic symmetry of the transverse
anisotropy imposes a selection rule on the total spin for the occurrence of the
Kondo effect which deviates from the usual even-odd alternation.Comment: 4 pages, 4 figure
Real-time renormalization group and cutoff scales in nonequilibrium applied to an arbitrary quantum dot in the Coulomb blockade regime
We apply the real-time renormalization group (RG) in nonequilibrium to an
arbitrary quantum dot in the Coulomb blockade regime. Within one-loop
RG-equations, we include self-consistently the kernel governing the dynamics of
the reduced density matrix of the dot. As a result, we find that relaxation and
dephasing rates generically cut off the RG flow. In addition, we include all
other cutoff scales defined by temperature, energy excitations, frequency, and
voltage. We apply the formalism to transport through single molecular magnets,
realized by the fully anisotropic Kondo model (with three different exchange
couplings J_x, J_y, and J_z) in a magnetic field h_z. We calculate the
differential conductance as function of bias voltage V and discuss a quantum
phase transition which can be tuned by changing the sign of J_x J_y J_z via the
anisotropy parameters. Finally, we calculate the noise S(Omega) at finite
frequency Omega for the isotropic Kondo model and find that the dephasing rate
determines the height of the shoulders in dS(\Omega)/d Omega near Omega=V.Comment: 16 pages, 7 figure
Oscillatory dynamics and non-markovian memory in dissipative quantum systems
The nonequilibrium dynamics of a small quantum system coupled to a
dissipative environment is studied. We show that (1) the oscillatory dynamics
close to a coherent-to-incoherent transition is surprisingly different from the
one of the classical damped harmonic oscillator and that (2) non-markovian
memory plays a prominent role in the time evolution after a quantum quench.Comment: 5 pages, 3 figure
Strong Tunneling in Double-Island Structures
We study the electron transport through a system of two low-capacitance metal
islands connected in series between two electrodes. The work is motivated in
part by experiments on semiconducting double-dots, which show intriguing
effects arising from coherent tunneling of electrons and mixing of the
single-electron states across tunneling barriers. In this article, we show how
coherent tunneling affects metallic systems and leads to a mixing of the
macroscopic charge states across the barriers. We apply a recently formulated
RG approach to examine the linear response of the system with high tunnel
conductances (up to 8e^2/h). In addition we calculate the (second order)
cotunneling contributions to the non-linear conductance. Our main results are
that the peaks in the linear and nonlinear conductance as a function of the
gate voltage are reduced and broadened in an asymmetric way, as well as shifted
in their positions. In the limit where the two islands are coupled weakly to
the electrodes, we compare to theoretical results obtained by Golden and
Halperin and Matveev et al. In the opposite case when the two islands are
coupled more strongly to the leads than to each other, the peaks are found to
shift, in qualitative agreement with the recent prediction of Andrei et al. for
a similar double-dot system which exhibits a phase transition.Comment: 12 page
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