19 research outputs found
Virtual Desktop Sizing
This paper is intended to describe a process of choosing and building a demo of virtualization solution for a group of people in campus of EPFL located in a city of Sion, Valais Wallis. The aim of the paper is to compare different desktop virtualization solutions and choose the best one within the given customer’s requirements and infrastructure. The second goal of the paper is to provide a demo implementation of the selected virtualization solution with guidelines describing how it was created and notes on specific customizations required within the given internal computer structure of the campus
Anomalous scaling at non-thermal fixed points of the sine-Gordon model
We extend the theory of non-thermal fixed points to the case of anomalously
slow universal scaling dynamics according to the sine-Gordon model. This
entails the derivation of a kinetic equation for the momentum occupancy of the
scalar field from a non-perturbative two-particle irreducible effective action,
which re-sums a series of closed loop chains akin to a large- expansion at
next-to-leading order. The resulting kinetic equation is analyzed for possible
scaling solutions in space and time that are characterized by a set of
universal scaling exponents and encode self-similar transport to low momenta.
Assuming the momentum occupancy distribution to exhibit a scaling form we can
determine the exponents by identifying the dominating contributions to the
scattering integral and power counting. If the field exhibits strong variations
across many wells of the cosine potential, the scattering integral is dominated
by the scattering of many quasiparticles such that the momentum of each single
participating mode is only weakly constrained. Remarkably, in this case, in
contrast to wave turbulent cascades, which correspond to local transport in
momentum space, our results suggest that kinetic scattering here is dominated
by rather non-local processes corresponding to a spatial containment in
position space. The corresponding universal correlation functions in momentum
and position space corroborate this conclusion. Numerical simulations performed
in accompanying work yield scaling properties close to the ones predicted here.Comment: 20 pages, 2 figures. Hyperlinks complete
Far-from-equilibrium universal scaling dynamics in ultracold atomic systems and heavy-ion collisions
Classification and understanding of scaling solutions in closed quantum systems far from thermal equilibrium, known as nonthermal fixed points, are one of the open problems in
nonequilibrium quantum many-body theory. The usual method involves searching for possible self-similar solutions to a (nonperturbative) evolution equation, e.g., Boltzmann or
Kadanoff–Baym, starting from a far-from-equilibrium initial condition. In this work, we develop an alternative approach based on the correspondence between scaling and fixed points of the renormalization group. Using an ultracold Bose gas as an example we show how possible far-from-equilibrium scaling solutions can be systematically obtained by solving fixed-point renormalization-group equations. In the second part of this thesis, we investigate dynamics preceding a fully developed self-similar evolution. We use the Hamiltonian
formulation of kinetic theory to perform a stability analysis of nonthermal fixed points in an expanding non-Abelian plasma characterized by the Fokker–Planck collision kernel. Employing an adiabatic expansion we develop a perturbation theory, which at next-to-leading order allows us to derive stability equations for scaling exponents and obtain the Lyapunov relaxation rates associated with a nonthermal fixed point
Femtosecond Circular Photon Drag Effect in the Ag/Pd Nanocomposite
Abstract
We report on the observation of the helicity-dependent photoresponse of the 20-\u3bcm-thick silver\u2013palladium (Ag/Pd) nanocomposite films. In the experiment, 120\ua0fs pulses of Ti:S laser induced in the film an electric current perpendicular to the incidence plane. The photoinduced current is a linear function of the incident beam power, and its sign depends on the beam polarization and angle of incidence. In particular, the current is zero for the p - and s -polarized beams, while its sign is opposite for the right- and left-circularly polarized beams. By comparing experimental results with theoretical analysis, we show that the photoresponse of the Ag/Pd nanocomposite originates from the photon drag effect
Stability analysis of nonthermal fixed points in longitudinally expanding kinetic theory
We use the Hamiltonian formulation of kinetic theory to perform a stability analysis of nonthermal fixed points in a non-Abelian plasma. We construct a perturbative expansion of the Fokker-Planck collision kernel in an adiabatic approximation and show that the (next-to-)leading order solutions reproduce the known nonthermal fixed point scaling exponents. Working at next-to-leading order, we derive the stability equations for scaling exponents and find the relaxation rate to the nonthermal fixed point. This approach provides the basis for an understanding of the prescaling phenomena observed in QCD kinetic theory and nonrelativistic Bose gas systems.We use the Hamiltonian formulation of kinetic theory to perform a stability analysis of non-thermal fixed points in a non-Abelian plasma. We construct a perturbative expansion of the Fokker-Planck collision kernel in an adiabatic approximation and show that the (next-to-)leading order solutions reproduce the known non-thermal fixed point scaling exponents. Working at next-to-leading order, we derive the stability equations for scaling exponents and find the relaxation rate to the non-thermal fixed point. This approach provides the basis for an understanding of the prescaling phenomena observed in QCD kinetic theory and non-relativistic Bose gas systems