The quantum roll in d-dimensions and the large-d expansion

Abstract

We investigate the quantum roll for a particle in a d-dimensional ``Mexican hat'' potential in quantum mechanics, comparing numerical simulations in d-dimensions with the results of a large-d expansion, up to order 1/d, of the coupled closed time path (CTP) Green's function equations, as well as to a post-Gaussian variational approximation in d-dimensions. The quantum roll problem for a set of N coupled oscillators is equivalent to a (d=N)-dimensional spherically symmetric quantum mechanics problem. For this problem the large-N expansion is equivalent to an expansion in 1/d where d is the number of dimensions. We use the Schwinger-Mahanthappa-Keldysh CTP formalism to determine the causal update equations to order 1/d. We also study the quantum fluctuations <r2> as a function of time and find that the 1/d corrections improve the agreement with numerical simulations at short times (over one or two oscillations) but beyond two oscillations, the approximation fails to correspond to a positive probability function. Using numerical methods, we also study how the long time behavior of the motion changes from its asymptotic (d ∞) harmonic behavior as we reduce d.