Your search keyword '"Deev, Evgeny V."' showing total 2 results

1. Travertines of the South-Eastern Gorny Altai (Russia): Implications for Paleoseismology and Paleoenvironmental Conditions.

Author

Deev, Evgeny V., Kokh, Svetlana N., Dublyansky, Yuri, Sokol, Ella V., Scholz, Denis, Rusanov, Gennady G., and Reutsky, Vadim N.

Subjects

*CALCITE, *TRAVERTINE, *EARTHQUAKE zones, *FAULT zones, *ALLUVIAL fans, *PALEOSEISMOLOGY, *WATER springs, *COLLUVIUM

Abstract

The south-eastern Gorny Altai is one of the most hazardous seismogenic area in the north of Central Asia. We present a synthesis of field, 230Th-U geochronological, mineralogical and geochemical data collected on seven Quaternary travertines. All travertines occur within the zones of active faults that border the Chuya and Kurai intermontane basins. Travertine cement mainly comprises calcite (with minor amounts of aragonite), which cements alluvial, alluvial fan, and colluvial deposits. The results of 230Th-U dating suggest that deposition of the travertines was triggered by large paleoearthquakes in the last eight thousand years. Several stages of travertine formation with ages 9–11 ka BP correspond to the known period of strong paleoseismicity in the region (8–16 ka BP). The 123 ka BP travertine resulted from a slip triggered by the Middle Pleistocene deglaciation, while that of 400 ka BP represents seismic motions likely associated with the main Cenozoic orogenic phase. All travertine forming events fall within warm and wet climatic phases (interglacials). Large earthquakes activated faults and caused a rapid rise along them of ambient-temperature bicarbonate groundwater, which was previously sealed in deep-seated Upper Neoproterozoic–Paleozoic limestone-dolostone aquifers. Rapid CO2 degassing of the spring water was the most important control of calcite or aragonite precipitation. Such travertines represent an important tool for paleoseismological research in seismically active regions. [ABSTRACT FROM AUTHOR]

Published

2023

2. Post-Late Glacial calcareous tufas from the Kurai fault zone (Southeastern Gorny Altai, Russia).

Author

Kokh, Svetlana N., Sokol, Ella V., Deev, Evgeny V., Ryapolova, Yuliya M., Rusanov, Gennady G., Tomilenko, Anatoliy A., and Bul'bak, Taras A.

Subjects

*CORALLINE algae, *TUFAS, *FAULT zones, *HOLOCENE Epoch, *GLACIERS

Abstract

Calcareous tufa deposits have been discovered in the Chibitka River valley near Lake Cheybek-Kohl, at the junction of the Kurai and Teletsk-Kurai large active faults in the southeastern Gorny Altai, Russia, at an altitude of 1800–2000 m. Fossil tufa is composed of calcite and cements Holocene grey colluvium and glacial till deposited by the Late Glacial Chibitka Glacier. Current tufa precipitation has been observed from a low-flow spring with cold (10 °C) HCO 3 -SO 4 –Ca-Mg water, рН = 6.86. The stable isotope composition of spring water is − 5.8‰ VPDB δ 13 C of dissolved inorganic carbon and − 14.5‰ VSMOW δ 18 O. Modern tufa consists of thin laminated Mg-calcite and Sr-aragonite crusts, with abundant algae and biofilms on their surfaces. Both modern and fossil tufas are depleted in REE (a total of 0.40–16.4 ppm and 0.40–3.80 ppm, respectively) and share similar PAAS-normalised REE + Y spectra with HREE enrichment and slight progressive LREE depletion. The modern tufas show positive δ 13 C values of 0.1‰ to 0.9‰ VPDB while the fossil ones have an isotopically lighter composition of δ 13 C = − 4.1‰ to − 1.9‰ VPDB; the δ 18 O range is very narrow (− 13.0 to − 13.8‰ VPDB). Both stable isotope and trace-element signatures (including REE patterns) of the tufas indicate precipitation from cold groundwaters subjected to prolonged interaction with a carbonate aquifer (the Baratal Group of limestone and dolostone) in a cold continental climate similar to the present conditions. Tufa deposition in the Lake Cheybek-Kohl area began with the onset of post-Late Glacial global warming and permafrost degradation. Unlike the fossil tufa formation, current precipitation of freshwater carbonates has been microbially mediated. The discovered tufa deposits provide new palaeoclimatic and active tectonic proxies in the southeastern Gorny Altai. [ABSTRACT FROM AUTHOR]

Published

2017