• journal_title：Geology
• Contributor：Aude Gébelin ; Andreas Mulch ; Christian Teyssier ; Micah J. Jessup ; Richard D. Law ; Maurice Brunel
• Publisher：Geological Society of America
• Date：2013-07-01
• Format：text/html
• Language：en
• Identifier：10.1130/G34331.1
• journal_abbrev：Geology
• issn：0091-7613
• volume：41
• issue：7
• firstpage：799
• section：Articles

The Neogene elevation history of the Mount Everest region is key for understanding the tectonic history of the world’s highest mountain range, the evolution of the Tibetan Plateau, and climate patterns in East and Central Asia. In the absence of fossil surface deposits such as paleosols, volcanic ashes, or lake sediments, we conducted stable isotope paleoaltimetry based on the hydrogen isotope ratios (δD) of hydrous minerals that were deformed in the South Tibetan detachment shear zone during the late Early Miocene. These minerals exchanged isotopically at high temperature with meteoric water (δD_water = −156‰ ± 5‰) that originated as high-elevation precipitation and infiltrated the crustal hydrologic system at the time of detachment activity. When compared to age-equivalent near-sea-level foreland oxygen isotope (δ¹⁸O) paleosol records (δ¹⁸O_water = −5.8‰ ± 1.0‰), the difference in δ¹⁸O_water is consistent with mean elevations of ≥5000 m for the Mount Everest area. Mean elevations similar to modern suggest that an early Himalayan rain shadow may have influenced the late Early Miocene climatic and rainfall history to the north of the Himalayan chain.