A Stratigraphic Record from 16 Ma to Present of Compound-Specific Hydrogen Isotopes from northern Tibet: Implications for Paleoaltimetry and Paleoclimate of the Northern Tibetan Plateau

The paleotopographic evolution of Tibet remains a key issue in testing models for the formation of orogenic plateaus. Stable isotopes from paleosols and lake carbonates provide the primary tool for estimating paleotopography. Unfortunately, the deposits are strongly controlled by evaporation, which means that the surface waters from which they formed were shifted towards heavier isotopic compositions relative to initial (pre-evaporation) meteoric compositions. As a result, estimates from these settings probably represent a lower bound for paleotopography. We report here on new analyses of compound-specific hydrogen stable isotopes, which were determined for n-alkanes extracts from 36 samples from Neogene strata in the northern Tibetan Plateau. N-alkanes represent long-chain hydrocarbons, commonly formed as leaf waxes in terrestrial high plants. The advantage of this record is that it is linked to times when moisture transport was high and evaporation low, as required to allow for the plants to thrive. Distributions of n-alkanes show maxima at C27, C29, and C31 with high odd-over-even preference values, suggesting excellent preservation of lipid biomarkers from terrestrial high plants. The deuterium values highly co-vary between three compounds. Application of an apparent fractionation factor based on modern ground waters and soil-derived lipid biomarkers suggest a multiple-phase evolution of paleometeoric waters consistent with well-constrained tectonic and climatic histories in the northern Tibetan Plateau. For example, a ~60‰ negative shift in δD between 16-10 Ma correlates well with sedimentological and thermochronologic evidence for rapid erosion at that time. The magnitude of this isotopic shift is equivalent to an increase in elevation of 2 to 3 km, assuming that the isotopic composition of the moisture source remained constant during this time. An abrupt positive δD shift at ~10 Ma is consistent with studies supporting intensified aridity in central Asia, whereas a negative δD shift at ~6.5 Ma potentially reflects a change to more moist conditions related to the onset/intensified East Asia Summer Monsoon. The attainment of high elevations in northern Tibetan Plateau is synchronous with the attainment of maximum elevation in the south-central Tibetan Plateau and with the transition from dominant tectonic extrusion to distributed crustal shortening in the northern Tibetan Plateau.