CONSTRAINTS ON THE VELOCITY STRUCTURE BENEATH THE TORNQUIST-TEISSEYREZONE FROM BEAM-FORMING ANALYSIS

The primary indicators of lateral heterogeneity in the Earth are the s lowness and azimuth of incoming seismic signals. On a regional scale, surface waves in the upper mantle and crust are often scattered and/or refracted, which results in deviations from the great-circle azimuth. The slowness and direction of propagation of an arriving wave packet provides information about the lateral heterogeneity, and can be measu red by performing beam-forming on the recordings across an array of st ations. The azimuthal deviation gives a constraint on the transverse v elocity gradient along the path. In addition, its frequency dependence gives information on the depth dependence of the heterogeneity. We ha ve performed beam-forming of fundamental-mode Rayleigh waves in the pe riod range of 20 to 100 s travelling from the south-east of Europe to the NARS-NL array in the Netherlands. The purpose of this study is to obtain new information about the velocity structure beneath the Tornqu ist-Teisseyre Zone (TTZ). The TTZ is known to be a transition between the higher seismic velocities in the thicker and older Precambrian cru st of the East European Platform (EEP), and the lower velocities in th e thinner and younger Palaeozioc crust of central and western Europe ( tectonic Europe, TE). However, the lateral velocity gradient and the d epth extent of this transition are not very well constrained. We have used events located at both sides of the TTZ, and both the direct Rayl eigh wave and its coda have been analysed. On the one hand, the deviat ion of the wave-propagation paths relative to the great circle observe d in the direct wave for the events on the eastern side of the TTZ con firms earlier results, i.e. it gives independent evidence for a thicke r crust and up to 10 per cent higher velocities in the first 150 km of the upper mantle beneath the EEP than beneath the TE. Such a contrast also explains observed surface head waves refracted along the TTZ. On the other hand, no energy reflected at the TTZ is detected in the cod a for the events on the western side. From synthetic experiments based on a linearized theory, we conclude that, from this absence of ref-le ctions, no lower bound can be imposed on the width of the transition z one across the TTZ at different depths. Source mechanisms other than t he ones for the events used are needed to observe these reflections at different depths, for both a sharp and a smooth transition.