Abstract
We use observations recorded by 23 permanent and 99 temporary stations in the SE Tibetan plateau to obtain the S-wave velocity structure along two profiles by applying joint inversion with receiver functions and surface waves. The two profiles cross West Yunnan block (WYB), the Central Yunnan sub-block (CYB), South China block (SCB), and Nanpanjiang basin (NPB). The profile at ~25°N shows that the Moho interface in the CYB is deeper than those in the WYB and the NPB, and the topography and Moho depth have clear correspondence. Beneath the Xiaojiang fault zone (XJF), there exists a crustal low-velocity zone (LVZ), crossing the XJF and expanding eastward into the SCB. The NPB is shown to be of relatively high velocity. We speculate that the eastward extrusion of the Tibetan plateau may pass through the XJF and affect its eastern region, and is resisted by the rigid NPB, which has high velocity. This may be the main cause of the crustal thickening and uplift of the topography. In the Tengchong volcanic area, the crust is shown to have alternate high- and low-velocity layers, and the upper mantle is shown to be of low velocity. We consider that the magma which exists in the crust is from the upper mantle and that the complex crustal velocity structure is related to magmatic differentiation. Between the Tengchong volcanic area and the XJF, the crustal velocity is relatively high. Combining these observations with other geophysical evidence, it is indicated that rock strength is high and deformation is weak in this area, which is why the level of seismicity is quite low. The profile at ~23°N shows that the variation of the Moho depth is small from the eastern rigid block to the western active block with a wide range of LVZs. We consider that deformation to the south of the SE Tibetan Plateau is weak.
Highlights
Collision between the Indian and Eurasian plates has induced intense orogenesis, produced many active faults, and caused material to escape from the Tibetan plateau (Molnar and Tapponnier 1975; Rowley 1996)
The low-velocity zone (LVZ) passes through the Xiaojiang fault zone (XJF) zone and seems to be resisted by the Nanpanjiang basin (NPB), which is of high velocity; this result differs little from previous understanding that the XJF is the boundary of the high-velocity eastern region and low-velocity western region
Profile BB0 (Fig. 5) shows a conspicuous variation in velocity within the West Yunnan block (WYB) and the NPB: the WYB has a wide range of crustal LVZs but NPB is shown to be of relatively high velocity
Summary
Collision between the Indian and Eurasian plates has induced intense orogenesis, produced many active faults, and caused material to escape from the Tibetan plateau (Molnar and Tapponnier 1975; Rowley 1996). To study the uplift and deformation mechanisms in this region, researchers have proposed many models, such as eastward extrusion of crustal material, crustal thickening and uplift of the plateau, or channel flow in a weak crust (Molnar and Tapponnier 1975; Tapponnier et al 1982; Allegre et al 1984; Royden et al 1997). With the intense crustal movement and strike-slip motion of the active faults, there is a clockwise rotation around the eastern Himalaya syntaxis in the SE Tibetan plateau (Replumaz and Tapponnier 2003; Shen et al 2001; Liang et al 2013), and the strong earthquakes occurred frequently (Fig. 1). Sun et al (2014) used dense seismic data from Chinarry to obtain the velocity structure of a profile They concluded that the two LVZs in the crust are crustal flow channels. Combining this with other research, we consider that the interpretation for the velocity structure should be a little different
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