Superoscillations for monochromatic standing waves

Abstract

For complex scalar waves, a convenient measure of the local oscillations and ('faster than Fourier') superoscillations is the phase gradient vector: The local wavevector, or weak value of the momentum operator. This vanishes for standing waves, described by real functions ψ( r ); for such waves, an alternative descriptor of oscillations is the local weak value of the square of one of the momentum components, i.e., here called the 'weak curvature'. Superoscillations correspond to places where K 2 lies outside the interval 0 K 2 1. Two illustrations are given. First is an explicit family of real waves in dimension d = 2, with arbitrarily strong superoscillations; this could represent Neumann standing modes in a strip waveguide. Second is an exact calculation of the probability distribution of K 2 for Gaussian random real waves in d dimensions. This decays as, as a consequence of the codimension 1 of nodes (e.g. nodal lines for d = 2). The superoscillation probability varies from 0.3918 (d = 2) to 0.3041 (d = ∞).