T. V. Dudnikova, A. I. Komech, N. J. Mauser
Published 2005-08-24Version 1
We consider the Dirac equation in $\R^3$ with constant coefficients and study the distribution $\mu_t$ of the random solution at time $t\in\R$. It is assumed that the initial measure $\mu_0$ has zero mean, a translation-invariant covariance, and finite mean charge density. We also assume that $\mu_0$ satisfies a mixing condition of Rosenblatt- or Ibragimov-Linnik-type. The main result is the convergence of $\mu_t$ to a Gaussian measure as $t\to\infty$. The proof uses the study of long time asymptotics of the solution and S.N. Bernstein's ``room-corridor'' method.
Comments: 12 pages
Journal: Russian J. Math. Physics, 10 (2003), no.4, 399-410
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