12,295 research outputs found
Fidelity amplitude of the scattering matrix in microwave cavities
The concept of fidelity decay is discussed from the point of view of the
scattering matrix, and the scattering fidelity is introduced as the parametric
cross-correlation of a given S-matrix element, taken in the time domain,
normalized by the corresponding autocorrelation function. We show that for
chaotic systems, this quantity represents the usual fidelity amplitude, if
appropriate ensemble and/or energy averages are taken. We present a microwave
experiment where the scattering fidelity is measured for an ensemble of chaotic
systems. The results are in excellent agreement with random matrix theory for
the standard fidelity amplitude. The only parameter, namely the perturbation
strength could be determined independently from level dynamics of the system,
thus providing a parameter free agreement between theory and experiment
Intrinsic quark transverse momentum in the nucleon from lattice QCD
A better understanding of transverse momentum (k_T-) dependent quark
distributions in a hadron is needed to interpret several experimentally
observed large angular asymmetries and to clarify the fundamental role of gauge
links in non-abelian gauge theories. Based on manifestly non-local gauge
invariant quark operators we introduce process-independent k_T-distributions
and study their properties in lattice QCD. We find that the longitudinal and
transverse momentum dependence approximately factorizes, in contrast to the
behavior of generalized parton distributions. The resulting quark
k_T-probability densities for the nucleon show characteristic dipole
deformations due to correlations between intrinsic k_T and the quark or nucleon
spin. Our lattice calculations are based on N_f=2+1 mixed action propagators of
the LHP collaboration.Comment: 4 pages, 3 figure
Dynamics of photoinduced Charge Density Wave-metal phase transition in K0.3MoO3
We present first systematic studies of the photoinduced phase transition from
the ground charge density wave (CDW) state to the normal metallic (M) state in
the prototype quasi-1D CDW system K0.3MoO3. Ultrafast non-thermal CDW melting
is achieved at the absorbed energy density that corresponds to the electronic
energy difference between the metallic and CDW states. The results imply that
on the sub-picosecond timescale when melting and subsequent initial recovery of
the electronic order takes place the lattice remains unperturbed.Comment: Phys. Rev. Lett., accepted for publicatio
Fidelity recovery in chaotic systems and the Debye-Waller factor
Using supersymmetry calculations and random matrix simulations, we studied
the decay of the average of the fidelity amplitude f_epsilon(tau)=<psi(0)|
exp(2 pi i H_epsilon tau) exp(-2 pi i H_0 tau) |psi(0)>, where H_epsilon
differs from H_0 by a slight perturbation characterized by the parameter
epsilon. For strong perturbations a recovery of f_epsilon(tau) at the
Heisenberg time tau=1 is found. It is most pronounced for the Gaussian
symplectic ensemble, and least for the Gaussian orthogonal one. Using Dyson's
Brownian motion model for an eigenvalue crystal, the recovery is interpreted in
terms of a spectral analogue of the Debye-Waller factor known from solid state
physics, describing the decrease of X-ray and neutron diffraction peaks with
temperature due to lattice vibrations.Comment: revised version (major changes), 4 pages, 4 figure
Optimizing the third-and-a-half post-Newtonian gravitational radiation-reaction force for numerical simulations
The gravitational radiation-reaction force acting on perfect fluids at 3.5
post-Newtonian order is cast into a form which is directly applicable to
numerical simulations. Extensive use is made of metric-coefficient changes
induced by functional coordinate transformations, of the continuity equation,
as well as of the equations of motion. We also present an expression
appropriate for numerical simulations of the radiation field causing the worked
out reaction force.Comment: 22 pages to appear in Physical Review
Non-Perturbative Dilepton Production from a Quark-Gluon Plasma
The dilepton production rate from the quark-gluon plasma is calculated from
the imaginary part of the photon self energy using a quark propagator that
contains the gluon condensate. The low mass dilepton rate obtained in this way
exhibits interesting structures (peaks and gaps), which might be observable at
RHIC and LHC.Comment: 16 pages, REVTEX, 8 PostScript figure
Relaxation properties of the quantum kinetics of carrier-LO-phonon interaction in quantum wells and quantum dots
The time evolution of optically excited carriers in semiconductor quantum
wells and quantum dots is analyzed for their interaction with LO-phonons. Both
the full two-time Green's function formalism and the one-time approximation
provided by the generalized Kadanoff-Baym ansatz are considered, in order to
compare their description of relaxation processes. It is shown that the
two-time quantum kinetics leads to thermalization in all the examined cases,
which is not the case for the one-time approach in the intermediate-coupling
regime, even though it provides convergence to a steady state. The
thermalization criterion used is the Kubo-Martin-Schwinger condition.Comment: 7 pages, 8 figures, accepted for publication in Phys. Rev.
Quantum kinetic description of Coulomb effects in one-dimensional nano-transistors
In this article, we combine the modified electrostatics of a one-dimensional
transistor structure with a quantum kinetic formulation of Coulomb interaction
and nonequilibrium transport. A multi-configurational self-consistent Green's
function approach is presented, accounting for fluctuating electron numbers. On
this basis we provide a theory for the simulation of electronic transport and
quantum charging effects in nano-transistors, such as gated carbon nanotube and
whisker devices and one-dimensional CMOS transistors. Single-electron charging
effects arise naturally as a consequence of the Coulomb repulsion within the
channel
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