Recent progress in seismic tomography and numerical simulations of seismic wave propagation have revealed the nature of heterogeneity and anisotropy in the upper mantle on a variety of scales. Surface wave tomography at lower frequency (5-50 mHz) have shown strong radial anisotropy with faster SH wave speeds than SV in the asthenosphere, particularly in the fast drifting oceanic and continental plates (e.g., Nettles & Dziewonski, 2008; Yoshizawa, 2014). Also, the existence of rapid vertical change of anisotropic properties has been found in continental lithosphere (Yoshizawa & Kennett, 2015), whose depth coincides well with the enigmatic Mid-Lithosphere Discontinuity from receiver functions.

At higher frequency (-10Hz), recent observations of scattered body waves require the existence of horizontally elongated small-scale heterogeneity in the lithosphere (e.g., Kennett & Furumura, 2008, 2013). The effects of such small-scale heterogeneities (correlation distance of kilometer-scale) have generally been ignored in surface wave propagation, whose wavelength is about several hundred kilometers. Such small-scale heterogeneity can, however, cause non-negligible influence on surface-wave phase speeds by changing the effective rigidity of the media and generating “apparent" radial anisotropy (SH>SV).

In this study, we investigate the effects of small-scale heterogeneity on the long-period surface waves through numerical experiments with normal mode calculations as well as 2-D finite-difference method simulations incorporating finely quasi-laminated heterogeneity in the upper mantle. We calculated dispersion curves using a bunch of 1-D velocity profiles including random heterogeneity in the upper mantle. The results suggest that the fine-scale heterogeneity makes the phase speeds of Rayleigh-wave slower, while those of Love-wave faster to some extent, generating apparent radial anisotropy, even though no effect of anisotropy is imposed on the velocity profiles.