L. Z. Granina scite author profile

The diatom £ora of the lake is currently dominated by several species, such as Aulacoseira baicalensis, A. islandica, Cyclotella minuta and Stephanodiscus binderanus v. baicalensis. All these species, except for C. minuta, have become more common in the lake in approximately the last 130 years, and we hypothesize that these changes may be attributed to a number of di¡erent processes linked to an ameliorating climate after the end of the Little Ice Age. The results presented here have important implications for this recently designated World Heritage Site, with regard to future pollution controls and catchment management policies.

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Origin and dynamics of Fe and Mn sedimentary layers in Lake Baikal

Granina

Müller

Wehrli

2004

Chemical Geology

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Ba and Ni speciation in a nodule of binary Mn oxide phase composition from Lake Baikal

Manceau

Kersten

Marcus

et al. 2007

Geochimica et Cosmochimica Acta

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Vivianite formation and distribution in Lake Baikal sediments

Fagel

Alleman

Granina

et al. 2005

Global and Planetary Change

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In an effort to better understand vivianite formation processes, four Lake Baikal sediment cores spanning two to four interglacial stages in the northern, central and southern basins and under various biogeochemical environments are scrutinized. The vivianite-rich layers were detected by anomalous P-enrichments in bulk geochemistry and visually by observations on X-radiographs. The millimetric concretions of vivianite were isolated by sieving and analysed by X-ray diffraction, scanning electron microscope (SEM), microprobe, infrared spectroscopy, inductively coupled plasma atomic emission spectrometry and mass spectrometry (ICP-AES, ICP-MS). All the vivianites display similar morphological, mineralogical and geochemical signature, suggesting a common diagenetic origin. Their geochemical signature is sensitive to secondary alteration where vivianite concretions are gradually transformed from the rim to the center into an amorphous santabarbaraite phase with a decreasing Mn content. We analysed the spatial and temporal distribution of the concretions in order to determine the primary parameters controlling the vivianite formation, e.g., lithology, sedimentation rates, and porewater chemistry. We conclude that vivianite formation in Lake Baikal is mainly controlled by porewater chemistry and sedimentation rates, and it is not a proxy for lacustrine paleoproductivity. Vivianite accumulation is not restricted to areas of slow sedimentation rates (e.g., Academician and Continent ridges). At the site of relatively fast sedimentation rate, i.e., the Posolsky Bank near the Selenga Delta, vivianite production may be more or less related to the Selenga River inputs. It could be also indirectly related to the past intensive methane escapes from the sediments. While reflecting an early diagenetic signal, the source of P and Fe porewater for vivianites genesis is still unclear.

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L. Z. Granina

Diatom succession trends in recent sediments from Lake Baikal and their relation to atmospheric pollution and to climate change

Origin and dynamics of Fe and Mn sedimentary layers in Lake Baikal

Ba and Ni speciation in a nodule of binary Mn oxide phase composition from Lake Baikal

Vivianite formation and distribution in Lake Baikal sediments

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