The reflection coefficient of a fractional reflector

Abstract

This paper considers the question of characterizing the behavior of waves reflected by a fractional singularity of the wave speed profile, i.e., of the form \[ c(x1, x2, x3) = c0 (1 + ( x1)+α )-1/2, \] for α > 0 not necessarily integer. We first focus on the case of one spatial dimension and a harmonic time dependence. We define the reflection coefficient R from a limiting absorption principle. We provide an exact formula for R in terms of the solution to a Volterra equation. We obtain the asymptotic limit of this coefficient in the large ω / c0 regime as \[ R = (α + 1)(2 i)α + 2 ( c0 ω )α + lower order terms. \] The amplitude is proportional to ω-α, and the phase rotation behavior is obtained from the i-(α+2) factor. The proof method does not rely on representing the solution by special functions, since α > 0 is general. In the multi-dimensional layered case, we obtain a similar result where the nondimensional variable ω / c0 is modified to account for the angle of incidence. The asymptotic analysis now requires the waves to be non-glancing. The resulting reflection coefficient can now be interpreted as a Fourier multiplier of order - α. In practice, the knowledge of the dependency of both the amplitude and the phase of R on ω and α might be able to inform the kind of signal processing needed to characterize the fractional nature of reflectors, for instance in geophysics.