Spinless particle in rapidly fluctuating random magnetic field
Abstract
We study a two-dimensional spinless particle in a disordered gaussian magnetic field with short time fluctuations, by means of the evolution equation for the density matrix <x(1) | (t)| x(2)>; in this description the two coordinates are associated with the retarded and advanced paths respectively. The static part of the vector potential correlator is assumed to grow with distance with a power h; the case h = 0 corresponds to a δ-correlated magnetic field, and h = 2 to free massless field. The value h = 2 separates two different regimes, diffusion and logarithmic growth respectively. When h < 2 the baricentric coordinate r = (1/2)(x(1) + x(2)) diffuses with a coefficient Dr proportional to x-h, where x is the relative coordinate: x = x(1) - x(2). As h > 2 the correlator of the magnetic field is a power of distance with positive exponent; then the coefficient Dr scales as x-2. The density matrix is a function of r and x2/t,and its width in r grows for large times proportionally to log(t/x2).
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