Quaternary Sedimentation and Subsidence History of Lake Baikal, Siberia, Based on Seismic Stratigraphy and Coring

Colman, Steven M.; Karabanov, E. B.; Nelson, Claudia

doi:10.1306/041703730941

Cited by 48 publications

(38 citation statements)

References 44 publications

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“…These two estimates suggest 100 m of sediment would require between ∼125 and 50 ka, much longer than the 40 ka constraint placed by the C 14 ages. The 0.8-2 mm/year sedimentation rates are consistent with long-term sedimentation rates in lakes in volcanically and tectonically active areas such as Lake Chalpas, Guatemala, and Lake Baikal in Siberia (Edgington et al, 1991;Fernex et al, 2001;Colman et al, 2003), with 2 mm/year being at the extreme. Thus, these are reasonable sedimentation rates, but they require more than 40 ka to build the ∼100 m sequence of sediments on Samosir.…”

Section: Modeling Resurgence At Tobasupporting

confidence: 70%

“…If the 74-33.7 ka rate was also 4.9 cm/year then the 500-400 m of uplift discussed above would have been achieved in ∼10-8 ka respectively, requiring sedimentation rates as high as 1-1.25 cm/year or 10-12.5 mm/year to produce the 100 m of sediment on Samosir before it emerged. Such rates are up to two orders of magnitude higher than sedimentation rates in the aforementioned lakes (Edgington et al, 1991;Fernex et al, 2001;Colman et al, 2003). We therefore consider uplift at the 33.7-22.5 ka rate of 4.9 cm/year untenable for the 74-33.7 ka period as it would require unrealistic sedimentation rates for Lake Toba.…”

Section: Modeling Resurgence At Tobamentioning

confidence: 99%

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Resurgent Tobaâ€”field, chronologic, and model constraints on time scales and mechanisms of resurgence at large calderas

et al. 2015

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Highlights• New data reveal for the first time a history of the last ∼33.7 ky of uplift of Samosir.• Minimum uplift rates were high (4.9 cm/year) for the first 11.2 ky but diminished after that to <1 cm/year for the last 22.5 ky.• Numerical modeling suggests that rebound of remnant magma augmented by deep recharge appears to be the most likely driver for uplift.• Detumescence makes a negligible contribution to resurgent uplift.• The volume of the resurgent dome is isostatically compensated by magma • Average rates of uplift at Toba are much lower than currently restless calderas indicating a distinction between resurgence and "restlessness".New data reveal details of the post-caldera history at the Earth's youngest resurgent supervolcano, Toba caldera in Sumatra. Resurgence after the caldera-forming ∼74 ka Youngest Toba Tuff eruption uplifted the caldera floor as a resurgent dome, Samosir Island, capped with 100 m of lake sediments. 14 C age data from the uppermost datable sediments reveal that Samosir Island was submerged beneath lake level (∼900 m a.s.l) at 33 ka. Since then, Samosir experienced 700 m of uplift as a tilted block dipping to the west. 14 C ages and elevations of sediment along a transect of Samosir reveal that minimum uplift rates were ∼4.9 cm/year from ∼33.7 to 22.5 ka, but diminished to ∼0.7 cm/year after 22.5 ka. Thermo-mechanical models informed by these rates reveal that detumescence does not produce the uplift nor the uplift rates estimated for Samosir. However, models calculating the effect of volume change of the magma reservoir within a temperature-dependent viscoelastic host rock reveal that a single pulse of ∼475 km 3 of magma produces a better fit to the uplift data than a constant flux. The cause of resurgent uplift of the caldera floor is rebound of remnant magma as the system re-established magmastatic and isostatic equilibrium after the caldera collapse. Previous assertions that the caldera floor was apparently at 400 m a.s.l or lower requires that uplift must have initiated between sometime between 33.7 and 74 ka at a minimum average uplift rate of ∼1.1 cm/year. The change in uplift rate from pre-33.7 ka to immediately post-33.7 ka suggests a role for deep recharge augmenting rebound. Average minimum rates of de Silva et al.Resurgence at Toba caldera, Sumatra resurgent uplift at Toba are at least an order of magnitude slower than net rates of "restlessness" at currently active calderas. This connotes a distinction between resurgence and "restlessness" controlled by different processes, scales of process, and controlling variables.

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Section: Modeling Resurgence At Tobasupporting

confidence: 70%

Section: Modeling Resurgence At Tobamentioning

confidence: 99%

Resurgent Tobaâ€”field, chronologic, and model constraints on time scales and mechanisms of resurgence at large calderas

et al. 2015

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“…The published interpretations about its lake-level fluctuations ranged between two contradicting estimations. Romashkin and Williams (1997) mentioned an extremely huge range of climatically induced lake-level fluctuations of about 450 m. Colman (1998) and Colman et al (2003), on the other hand, refused the possibility of considerable climatically induced lake-level changes for Lake Baikal. The authors pointed out that the observed relative lakelevel changes were mainly caused by tectonic activity.…”

Section: Comparison With Other Records From Lake El'gygytgynmentioning

confidence: 99%

Late Quaternary lake-level changes of Lake El'gygytgyn, NE Siberia

et al. 2011

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Lake El'gygytgyn is situated in a 3.6 Ma old impact crater in northeastern Siberia. Presented here is a reconstruction of the Quaternary lake-level history as derived from sediment cores from the southern lake shelf. There, a cliff-like bench 10 m below the modern water level has been investigated. Deep-water sediments on the shelf indicate high lake levels during a warm Mid-Pleistocene period. One period with low lake level prior to Marine Oxygen Isotope Stage (MIS) 3 has been identified, followed by a period of high lake level (10 m above present). In the course of MIS 2 the lake level dropped to − 10 m. At the end of MIS 2 the bench was formed and coarse beach sedimentation occurred. Subsequently, the lake level rose rapidly to the Holocene level. Changes in water level are likely linked to climate variability. During relatively temperate periods the lake becomes free of ice in summer. Strong wave actions transport sediment parallel to the coast and towards the outlet, where the material tends to accumulate, resulting in lake level rise. During cold periods the perennial lake ice cover hampers any wave activity and pebble-transport, keeping the outlet open and causing the lake level to drop.

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“…Turbidites represent deposits of turbulent, high-energy conditions, triggered by catastrophic events: breakdowns of delta slopes, voluminous mud flows and excessive floods in the catchment (Sturm and Matter, 1978;Girardclos et al, 2007). Alterations of pelagic mud and turbidites indicate that normally calm sedimentation conditions within the deep basins of Lake Baikal are interrupted occasionally by high-energy turbidity currents and by rapid re-deposition of older material from far distance sources (Nelson et al, 1999;Colman et al, 2003;Vologina et al, 2003). Analogical, we suggest distant sources for the turbidites of the deep-water cores BAIK00-1 and BAIK08-2 (Fig.…”

Section: Mineralsmentioning

confidence: 99%

“…It has been shown that biological, physical and geochemical processes all influence biological and geochemical variability in the lake Flower, 1998;Müller et al, 2005;Granina and Callender, 2007;Schmid et al, 2008). Detailed studies of the lake bottom morphology and of composition and age of sediments in the different basins have been used, to further our understanding of processes of sediment formation and accumulation in Lake Baikal (Potrik'eva, 1959;Karabanov et al, 1984;Appleby et al, 1998;De Batist et al, 2002;Colman et al, 2003;Vologina and Sturm, 2009) and to studying past environmental and climate changes (Kuzmin et al, 2000;Bangs et al, 2000;Grachev et al, 2002;Fietz et al, 2005;Mackay, 2007). Formation and deposition of turbidities within the deep basins of Lake Baikal have been investigated and described within the conceptual principles of turbidity current formation in freshwater basins (Sturm and Matter, 1978).…”

Section: Introductionmentioning

confidence: 99%

Holocene and Late Glacial sedimentation near steep slopes in southern Lake Baikal

2015

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Quaternary Sedimentation and Subsidence History of Lake Baikal, Siberia, Based on Seismic Stratigraphy and Coring

Cited by 48 publications

References 44 publications

Resurgent Tobaâ€”field, chronologic, and model constraints on time scales and mechanisms of resurgence at large calderas

Resurgent Tobaâ€”field, chronologic, and model constraints on time scales and mechanisms of resurgence at large calderas

Late Quaternary lake-level changes of Lake El'gygytgyn, NE Siberia

Holocene and Late Glacial sedimentation near steep slopes in southern Lake Baikal

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