55 research outputs found

    Dissipative quantum systems modeled by a two level reservoir coupling

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    The coupling between a quantum dynamical system and a two-level system reservoir is analysed within the framework of the Feynman-Vernon theory. We stress the differences between this new reservoir and the well-known bath of oscillators and show that, in order to obtain the Langevin equation for the system of interest in the high temperature regime, we have to choose a spectral distribution function J(ω)J(\omega) which is finite for ω=0\omega=0.Comment: 6 pages, RevteX, preprint UNICAM

    Dynamic rotor mode in antiferromagnetic nanoparticles

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    We present experimental, numerical, and theoretical evidence for a new mode of antiferromagnetic dynamics in nanoparticles. Elastic neutron scattering experiments on 8 nm particles of hematite display a loss of diffraction intensity with temperature, the intensity vanishing around 150 K. However, the signal from inelastic neutron scattering remains above that temperature, indicating a magnetic system in constant motion. In addition, the precession frequency of the inelastic magnetic signal shows an increase above 100 K. Numerical Langevin simulations of spin dynamics reproduce all measured neutron data and reveal that thermally activated spin canting gives rise to a new type of coherent magnetic precession mode. This "rotor" mode can be seen as a high-temperature version of superparamagnetism and is driven by exchange interactions between the two magnetic sublattices. The frequency of the rotor mode behaves in fair agreement with a simple analytical model, based on a high temperature approximation of the generally accepted Hamiltonian of the system. The extracted model parameters, as the magnetic interaction and the axial anisotropy, are in excellent agreement with results from Mossbauer spectroscopy

    Magnetoresistance of Two-Dimensional Fermions in a Random Magnetic Field

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    We perform a semiclassical calculation of the magnetoresistance of spinless two-dimensional fermions in a long-range correlated random magnetic field. In the regime relevant for the problem of the half filled Landau level the perturbative Born approximation fails and we develop a new method of solving the Boltzmann equation beyond the relaxation time approximation. In absence of interactions, electron density modulations, in-plane fields, and Fermi surface anisotropy we obtain a quadratic negative magnetoresistance in the weak field limit.Comment: 12 pages, Latex, no figures, Nordita repor

    Semiclassical theory of transport in a random magnetic field

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    We study the semiclassical kinetics of 2D fermions in a smoothly varying magnetic field B(r)B({\bf r}). The nature of the transport depends crucially on both the strength B0B_0 of the random component of B(r)B({\bf r}) and its mean value Bˉ\bar{B}. For Bˉ=0\bar{B}=0, the governing parameter is α=d/R0\alpha=d/R_0, where dd is the correlation length of disorder and R0R_0 is the Larmor radius in the field B0B_0. While for α1\alpha\ll 1 the Drude theory applies, at α1\alpha\gg 1 most particles drift adiabatically along closed contours and are localized in the adiabatic approximation. The conductivity is then determined by a special class of trajectories, the "snake states", which percolate by scattering at the saddle points of B(r)B({\bf r}) where the adiabaticity of their motion breaks down. The external field also suppresses the diffusion by creating a percolation network of drifting cyclotron orbits. This kind of percolation is due only to a weak violation of the adiabaticity of the cyclotron rotation, yielding an exponential drop of the conductivity at large Bˉ\bar{B}. In the regime α1\alpha\gg 1 the crossover between the snake-state percolation and the percolation of the drift orbits with increasing Bˉ\bar{B} has the character of a phase transition (localization of snake states) smeared exponentially weakly by non-adiabatic effects. The ac conductivity also reflects the dynamical properties of particles moving on the fractal percolation network. In particular, it has a sharp kink at zero frequency and falls off exponentially at higher frequencies. We also discuss the nature of the quantum magnetooscillations. Detailed numerical studies confirm the analytical findings. The shape of the magnetoresistivity at α1\alpha\sim 1 is in good agreement with experimental data in the FQHE regime near ν=1/2\nu=1/2.Comment: 22 pages REVTEX, 14 figure

    The GNP Testbed for Operator Support Evaluation

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    Nanoelectromechanical switch operating by tunneling of an entire C-60 molecule

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    We present a solid state single molecule electronic device where switching between two states with different conductance happens predominantly by tunneling of an entire C-60 molecule. This conclusion is based on a novel statistical analysis of similar to 10(5) switching events. The analysis yields (i) the relative contribution of tunneling, current induced heating and thermal fluctuations to the switching mechanism, (ii) the voltage dependent energy barrier (similar to 100-200 meV) separating the two states of the switch and (iii) the switching attempt frequency, omega(0) corresponding to a 2.8 meV mode, which is most likely rotational

    Nanoelectromechanical switch operating by tunneling of an entire C-60 molecule

    No full text
    We present a solid state single molecule electronic device where switching between two states with different conductance happens predominantly by tunneling of an entire C-60 molecule. This conclusion is based on a novel statistical analysis of similar to 10(5) switching events. The analysis yields (i) the relative contribution of tunneling, current induced heating and thermal fluctuations to the switching mechanism, (ii) the voltage dependent energy barrier (similar to 100-200 meV) separating the two states of the switch and (iii) the switching attempt frequency, omega(0) corresponding to a 2.8 meV mode, which is most likely rotational
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