Eocene deformation of the NE Tibetan Plateau: Indications from magnetostratigraphic constraints on the oldest sedimentary sequence in the Linxia Basin

Abstract

The process and mechanism of deformation in the northeastern Tibetan Plateau (NETP) are significant for understanding the remote effects of the India-Eurasia collision. Although increasingly more research has extensively addressed the post-Oligocene NETP growth history over the past two decades, geological dating of early Cenozoic sediments remains sparse, hampering our understanding of early-stage tectonic growth in this region. Here, we present magnetostratigraphic results from the oldest sedimentary record between ~54 and 40 Ma in the western part of the Linxia Basin based on correlation with the geomagnetic polarity time scale. This age exceeds that of the oldest strata previously known (29 Ma) and has great potential for recording paleoclimatic and paleontological evolution in the fossil-rich Linxia Basin. Integrating our paleomagnetic chronology, sedimentary facies, accumulation rate, and provenance results reveals that early-stage Linxia Basin development was associated with Eocene growth of the West Qinling. The U-Pb age distributions of detrital grains from pre-51 Ma strata are characterized by many 200–300 Ma ages; alluvial fans and north-directed paleocurrent data indicate a single and relatively proximal source. The northern segment of the West Qinling was the predominant source supplying sediments to the Linxia Basin before ~51 Ma. Subsequently, a pronounced increase in the sedimentation rate at ~51 Ma and southward migration of the sedimentary system during 51–47.8 Ma demonstrate that extension and fast exhumation of the sediment source occurred. Detrital zircon U-Pb age spectra since ~51 Ma reveal significant increases in Precambrian peaks (1500–2000 Ma and 2300–2600 Ma). These observations suggest accelerated growth of the southern segment of the West Qinling and/or eastern segment of the East Kunlun Shan between 51 and 47.8 Ma. The Eocene basin evolution and accelerated uplift of ranges in the NETP imply near-synchronicity of crustal shortening and deformation across the entire India-Eurasia collision zone.