363 research outputs found

    Approach to equilibrium for the phonon Boltzmann equation

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    We study the asymptotics of solutions of the Boltzmann equation describing the kinetic limit of a lattice of classical interacting anharmonic oscillators. We prove that, if the initial condition is a small perturbation of an equilibrium state, and vanishes at infinity, the dynamics tends diffusively to equilibrium. The solution is the sum of a local equilibrium state, associated to conserved quantities that diffuse to zero, and fast variables that are slaved to the slow ones. This slaving implies the Fourier law, which relates the induced currents to the gradients of the conserved quantities.Comment: 23 page

    Infinite dimensional SRB measures

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    We review the basic steps leading to the construction of a Sinai-Ruelle-Bowen (SRB) measure for an infinite lattice of weakly coupled expanding circle maps, and we show that this measure has exponential decay of space-time correlations. First, using the Perron-Frobenius operator, one connects the dynamical system of coupled maps on a dd-dimensional lattice to an equilibrium statistical mechanical model on a lattice of dimension d+1d+1. This lattice model is, for weakly coupled maps, in a high-temperature phase, and we use a general, but very elementary, method to prove exponential decay of correlations at high temperatures.Comment: 19 page

    Global Large Time Self-similarity of a Thermal-Diffusive Combustion System with Critical Nonlinearity

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    We study the initial value problem of the thermal-diffusive combustion system: u1,t=u1,x,x−u1u22,u2,t=du2,xx+u1u22,x∈R1u_{1,t} = u_{1,x,x} - u_1 u^2_2, u_{2,t} = d u_{2,xx} + u_1 u^2_2, x \in R^1, for non-negative spatially decaying initial data of arbitrary size and for any positive constant dd. We show that if the initial data decays to zero sufficiently fast at infinity, then the solution (u1,u2)(u_1,u_2) converges to a self-similar solution of the reduced system: u1,t=u1,xx−u1u22,u2,t=du2,xxu_{1,t} = u_{1,xx} - u_1 u^2_2, u_{2,t} = d u_{2,xx}, in the large time limit. In particular, u1u_1 decays to zero like O(t−12−δ){\cal O}(t^{-\frac{1}{2}-\delta}), where δ>0\delta > 0 is an anomalous exponent depending on the initial data, and u2u_2 decays to zero with normal rate O(t−12){\cal O}(t^{-\frac{1}{2}}). The idea of the proof is to combine the a priori estimates for the decay of global solutions with the renormalization group (RG) method for establishing the self-similarity of the solutions in the large time limit.Comment: 22pages, Latex, [email protected],[email protected], [email protected]

    Probabilistic estimates for the Two Dimensional Stochastic Navier-Stokes Equations

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    We consider the Navier-Stokes equation on a two dimensional torus with a random force, white noise in time and analytic in space, for arbitrary Reynolds number RR. We prove probabilistic estimates for the long time behaviour of the solutions that imply bounds for the dissipation scale and energy spectrum as R→∞R\to\infty.Comment: 10 page

    Some new results on an old controversy: is perturbation theory the correct asymptotic expansion in nonabelian models?

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    Several years ago it was found that perturbation theory for two-dimensional O(N) models depends on boundary conditions even after the infinite volume limit has been taken termwise, provided N>2N>2. There ensued a discussion whether the boundary conditions introduced to show this phenomenon were somehow anomalous and there was a class of `reasonable' boundary conditions not suffering from this ambiguity. Here we present the results of some computations that may be interpreted as giving some support for the correctness of perturbation theory with conventional boundary conditions; however the fundamental underlying question of the correctness of perturbation theory in these models and in particular the perturbative β\beta function remain challenging problems of mathematical physics.Comment: 4 pages, 3 figure

    Renormalization Group and Asymptotics of Solutions of Nonlinear Parabolic Equations

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    We present a general method for studying long time asymptotics of nonlinear parabolic partial differential equations. The method does not rely on a priori estimates such as the maximum principle. It applies to systems of coupled equations, to boundary conditions at infinity creating a front, and to higher (possibly fractional) differential linear terms. We present in detail the analysis for nonlinear diffusion-type equations with initial data falling off at infinity and also for data interpolating between two different stationary solutions at infinity.Comment: 29 page

    KAM Theorem and Quantum Field Theory

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    We give a new proof of the KAM theorem for analytic Hamiltonians. The proof is inspired by a quantum field theory formulation of the problem and is based on a renormalization group argument treating the small denominators inductively scale by scale. The crucial cancellations of resonances are shown to follow from the Ward identities expressing the translation invariance of the corresponding field theory.Comment: 32 page

    Relaxation to quantum equilibrium for Dirac fermions in the de Broglie-Bohm pilot-wave theory

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    Numerical simulations indicate that the Born rule does not need to be postulated in the de Broglie-Bohm pilot-wave theory, but arises dynamically (relaxation to quantum equilibrium). These simulations were done for a particle in a two-dimensional box whose wave-function obeys the non-relativistic Schroedinger equation and is therefore scalar. The chaotic nature of the de Broglie-Bohm trajectories, thanks to the nodes of the wave-function which act as vortices, is crucial for a fast relaxation to quantum equilibrium. For spinors, we typically do not expect any node. However, in the case of the Dirac equation, the de Broglie-Bohm velocity field has vorticity even in the absence of nodes. This observation raises the question of the origin of relaxation to quantum equilibrium for fermions. In this article, we provide numerical evidence to show that Dirac particles also undergo relaxation, by simulating the evolution of various non-equilibrium distributions for two-dimensional systems (the 2D Dirac oscillator and the Dirac particle in a spherical 2D box).Comment: 11 pages, 9 figure
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