Lithosphere and asthenosphere of the Tien Shan imaged by S receiver functions

Abstract: [1] The S receiver function technique was applied to the recordings from 36 broad-band stations in the Tien Shan. The results reveal a pronounced difference in the properties of the lithosphereasthenosphere of the Tien Shan and those of the neighboring platforms. Beneath the Tien Shan, an upper-mantle lid with an S velocity of about 4.5 km/s is underlain at a depth of about 90 km by a low-velocity zone, where the S velocity drops to 4.1 -4.2 km/ s. Trends of P and S travel time residuals are consistent with th… Show more

“…Ambient noise tomography manifested low velocity within the mantle lid beneath the Tienshan orogenic belt (Li et al, 2012). Receiver function analyses showed a crustal thickness of ~60 km beneath the most parts of the Tienshan orogenic belt with variations of ~20 km under the adjacent platforms (Bump and Sheehan, 1998;Oreshin et al, 2002;Vinnik et al, 2004;Kumar et al, 2005). Tian et al (2010) suggested that the detached lithosphere may have descended to the bottom of the mantle transition zone and small-scale upwelling may have ascended from the lower mantle beneath the central Tienshan and adjacent regions.…”

Pn anisotropic tomography under the entire Tienshan orogenic belt

“…Ambient noise tomography manifested low velocity within the mantle lid beneath the Tienshan orogenic belt (Li et al, 2012). Receiver function analyses showed a crustal thickness of ~60 km beneath the most parts of the Tienshan orogenic belt with variations of ~20 km under the adjacent platforms (Bump and Sheehan, 1998;Oreshin et al, 2002;Vinnik et al, 2004;Kumar et al, 2005). Tian et al (2010) suggested that the detached lithosphere may have descended to the bottom of the mantle transition zone and small-scale upwelling may have ascended from the lower mantle beneath the central Tienshan and adjacent regions.…”

Pn anisotropic tomography under the entire Tienshan orogenic belt

“…Despite these complications, there has been renewed interest in recent years in teleseismic S-to-P conversions as means of characterizing the lithosphere to asthenosphere boundary (e.g., Kawakatsu et al, 2009;Kumar et al, 2005;Li et al, 2004;Oreshin et al, 2002;Rychert et al, 2007;Vinnik et al, 2005;Yuan et al, 2006). The growing waveform archive afforded by the profusion of modern digital networks has enabled stacking of large quantities of data to mitigate the low signal-to-noise ratios that characterize these phases, resulting in important new insights into this enigmatic structure (Eaton et al, 2009;Rychert et al, 2010).…”

Theory and Observations - Seismology and the Structure of the Earth: Teleseismic Body-Wave Scattering and Receiver-Side Structure

“…In a narrow corridor along the island chain, the LAB is observed to thin to $60 km at the northwest end of the chain. Oreshin et al (2002) found the LAB at 90 km depth beneath the Tian Shan from S receiver functions. Revenaugh and Jordan (1991b) found the LAB at 60 km depth from longperiod ScS reverberations in several regions of the western Pacific, but did not observe it in continental regions.…”

Deep Earth Structure – Transition Zone and Mantle Discontinuities