Spectral form factor in a random matrix theory

In the theory of disordered systems the spectral form factor S (), the Fourier transform of the two-level correlation function with respect to the difference of energies, is linear for ₂ and constant for >₂. Near zero and near ₂ it exhibits oscillations which have been discussed in several recent papers. In problems of mesoscopic fluctuations and quantum chaos a comparison is often made with a random matrix theory. It turns out that, even in the simplest Gaussian unitary ensemble, these oscillations have not yet been studied there. For random matrices, the two-level correlation function (₁, ₂) exhibits several well-known universal properties in the large-N limit. Its Fourier transform is linear as a consequence of the short-distance universality of (₁, ₂). However the crossover near zero and ₂ requires one to study these correlations for finite N. For this purpose we use an exact contour-integral representation of the two-level correlation function which allows us to characterize these crossover oscillatory properties. This representation is then extended to the case in which the Hamiltonian is the sum of a deterministic part H₀ and of a Gaussian random potential V. Finally, we consider the extension to the time-dependent case.