Eolian dust forcing of river chemistry on the northeastern Tibetan Plateau since 8 Ma

Eolian dust is one of the most important factors controlling fluvial hydrological evolution in modern arid and semi-arid central Asia. Here, we present the bulk carbonate Ca–Mg–Sr concentrations and Sr isotopic compositions recorded in water soluble salts, carbonate and silicate fractions, as well a...

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Published inEarth and planetary science letters Vol. 464; pp. 200 - 210
Main Authors Yang, Yibo, Galy, Albert, Fang, Xiaomin, Yang, Rongsheng, Zhang, Weilin, Zan, Jinbo
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.04.2017
Elsevier
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Summary:Eolian dust is one of the most important factors controlling fluvial hydrological evolution in modern arid and semi-arid central Asia. Here, we present the bulk carbonate Ca–Mg–Sr concentrations and Sr isotopic compositions recorded in water soluble salts, carbonate and silicate fractions, as well as the Nd isotopic compositions in the silicate fraction of a Late Miocene (12.2–5.1 Ma) fluvial sequence exhibiting paleosol development, in the Linxia Basin on the northeastern Tibetan Plateau (TP). Bulk carbonate Mg–Sr systematics show a distinct pattern in log–log plots of Mg/Ca versus log Sr/Ca ratios, and clearly higher 87Sr/86Sr ratios since ∼8 Ma. These findings cannot be adequately explained by the mechanism of prior calcite precipitation (PCP) – this latter process results in a positive correlation between the Mg/Ca and Sr/Ca ratios in authigenic calcite, evident in the fixed gradient in their log–log plots and has been isolated as being the major factor controlling carbonate Mg–Sr systematics before 8 Ma. Nor can these findings be explained by other mechanisms related to the catchment's provenance/sedimentation. The dramatic changes in carbonate Sr contents, Sr isotopes, and Sr/Mg ratios since ∼8 Ma may therefore be inferred to have been triggered by significant inputs of eolian dust via the dissolution of dust carbonates and evaporites in the paleowaters where fluvial and paleosol carbonates precipitated. This process of eolian dust input can be reliably illustrated using a binary mixing model corresponding to a series of varying PCP fluxes (identical to processes affecting the area before 8 Ma) combined with a constant eolian influx calculated from the co-variations between Mg/Ca, Sr/Ca and Sr isotopic ratios. Eolian dust also leaves a fingerprint in the carbonate and silicate minerals of bulk sediments, as revealed respectively by their Sr and Nd isotopic compositions. Eolian dust compositions for the ∼8–5 Ma on the northeastern TP can thus be taken to be characterized by a εNd value ≤−10.5 for the silicate fraction, and by a 87Sr/86Sr value ≥0.7115 for the labile faction (carbonates and evaporites). Eolian dust is now recognized to have made a significant impact on the hydrological evolution of arid and semi-arid northern China as far back as ∼8 Ma, suggesting an enhanced regime of dust activity and regional aridification in central Asia at that time. •A 12.2–5.1 Ma fluvial carbonate record in the Linxia Basin on the NE Tibet.•Both bulk carbonate Mg/Ca and Sr/Ca ratios decrease since ∼8 Ma.•High carbonate and soluble salt 87Sr/86Sr and more negative silicate εNd by ∼8 Ma.•Aeolian dust forcing of fluvial hydrology and authigenic carbonate composition.•Enhanced central Asia drying and dust activity since ∼8 Ma.
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2017.02.009