In the O'Doherty-Anstey model, the spectrum of a seismic wave transiting and reverberating within a stack of interfaces is estimated in terms of its reflectivity. At the center of the model is a discrete combinatorical calculation, in which the contributing raypaths at each lag are weighted and counted. The model maps naturally into an analysis based on statistical mechanics, with raypaths playing the role of sys-tem configurations and lag playing the role of system energy. This leads to an expression for the probability of finding a contribution to the wave at a given lag, determined up to a partition function and a scattering parameter analogous to temperature. The partition function is estimated within the O'Doherty-Anstey model itself, and the scattering parameter can be adjusted to describe geologic media with increased or decreased scattering potential. The average contributing lag deriving from this analysis exhibits a continuous phase tran-sition, separating two distinct scattering regimes, one in which the direct wave dominates and the other in which the scatter-ing dominates. The weighting produced by the reflectivity ap-pears to govern the smoothness of the transition.
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