Patient-Reported Outcome Measures for the Knee

The dynamics of a quantum plasma can be described self-consistently by the nonlinear Schrödinger-Poisson system. Here, we consider a multistream model representing a statistical mixture of N pure states, each described by a wavefunction. The one-stream and two-stream cases are investigated. We derive the dispersion relation for the two-stream instability and show that a new, purely quantum, branch appears. Numerical simulations of the complete Schrödinger-Poisson system confirm the linear analysis, and provide further results in the strongly nonlinear regime. The stationary states of the Schrödinger-Poisson system are also investigated. These can be viewed as the quantum mechanical counterpart of the classical Bernstein-Greene-Kruskal modes, and are described by a set of coupled nonlinear differential equations for the electrostatic potential and the stream amplitudes.

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Entropy and Wigner functions

Manfredi¹,

Feix

2000

Phys. Rev. E

111

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The properties of an alternative definition of quantum entropy, based on Wigner functions, are discussed. Such a definition emerges naturally from the Wigner representation of quantum mechanics, and can easily quantify the amount of entanglement of a quantum state. It is shown that smoothing of the Wigner function induces an increase in entropy. This fact is used to derive some simple rules to construct positive-definite probability distributions which are also admissible Wigner functions.

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On the singularity analysis of ordinary differential equations invariant under time translation and rescaling

Feix

Géronimi

Cairó

et al. 1997

J. Phys. A: Math. Gen.

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Stability of Bernstein–Greene–Kruskal plasma equilibria. Numerical experiments over a long time

Ghizzo

Izrar

Bertrand

et al. 1988

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Bernstein–Greene–Kruskal (BGK) equilibria for a Vlasov plasma consisting of a periodic structure exhibiting depressions or ‘‘holes’’ in phase space are under consideration. Marginal stability analysis indicates that such structures are unstable when the system contains at least two holes. An Eulerian numerical code is developed allowing noiseless information on the long time phase space behavior (about 103ω−1p) to be obtained. Starting with equilibria with up to six holes, it is shown that the final state is given by a structure with only one large hole, the initial instability inducing coalescences of the different holes. On the other hand, starting with a homogeneous two-stream plasma it is shown that, in a first step, a BGK periodic structure appears with a number of holes proportional to the length of the system, followed, in a second step, by a coalescence of the holes to always end up with the above mentioned one large hole structure.

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Marc Feix

Multistream model for quantum plasmas

Entropy and Wigner functions

On the singularity analysis of ordinary differential equations invariant under time translation and rescaling

Stability of Bernstein–Greene–Kruskal plasma equilibria. Numerical experiments over a long time

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