Skip to Main Content
Skip Nav Destination

Iron-manganese formations in the Baikal region

Russ. Geol. Geophys. (2010) 51 (6): 650–660.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
Precise regulation of the phase transformation for pyrolusite during the reduction roasting process
International Journal of Minerals, Metallurgy and Materials (2024) 31 (1): 81.
Natural and anthropogenic impacts on Lake Ladoga and its catchment area through the late glacial and Holocene according to a new paleolimnological record
Journal of Paleolimnology (2024) 72 (2): 241.
Extracting paleo-weathering signals from authigenic phases in lake sediments: A case-study of Lake Baikal
Chemical Geology (2024) 654: 122054.
The green reductive leaching of manganiferous iron ore and Mn3O4 nanoparticles production: Kinetic modeling and comparison of various reductants
Journal of the Taiwan Institute of Chemical Engineers (2024) 159: 105479.
Microbial Communities in Ferromanganese Sediments from the Northern Basin of Lake Baikal (Russia)
Microorganisms (2023) 11 (7): 1865.
Bir mangan cevheri için yer çekimi ile zenginleştirme akım şeması oluşturma çalışmaları
Yerbilimleri/Hacettepe Üniversitesi Yerbilimleri Uygulama ve Araştırma Merkezi Dergisi (2022)
Microbial Communities of Ferromanganese Sedimentary Layers and Nodules of Lake Baikal (Bolshoy Ushkany Island)
Diversity (2022) 14 (10): 868.
Preservation of Fe/Mn‐redox fronts in sediments of an oligotrophic, oxygenated deep‐water lake (Lago Fagnano, Tierra del Fuego)
Sedimentology (2022) 69 (4): 1841.
Multielement analysis of continental and lacustrine ferromanganese nodules by WDXRF, TXRF, and ICP-MS methods. Intercomparison study and accuracy assessment
Applied Radiation and Isotopes (2021) 178: 109981.
Source Apportionment of Inorganic Solutes in Surface Waters of Lake Baikal Watershed
Sustainability (2021) 13 (10): 5389.
Use of Methods of Electronic Microscopy, Mass-Spectrometry and Roentgenospectral Electronic Probe Micro-Analyzer in Ecological and Analytical Studies. Elemental Composition of Blue Micro-Particles of Unknown Nature Observed in Suspended Substance of Lake Baikal
Bulletin of Baikal State University (2020) 29 (4): 533.
Distribution of Elements in Iron-Manganese Formations in Bottom Sediments of Lake Onego (NW Russia) and Small Lakes (Shotozero and Surgubskoe) of Adjacent Territories
Minerals (2020) 10 (5): 440.
Individual enrichment of manganese and iron from complex refractory ferromanganese ore by suspension magnetization roasting and magnetic separation
Powder Technology (2020) 373: 689.
Extraction and separation of manganese and iron from ferruginous manganese ores: A review
Minerals Engineering (2019) 131: 286.
Electrical, mineralogical, and geochemical properties of Um Gheig and Um Bogma Formations, Egypt
Carbonates and Evaporites (2019) 34 (4): 1251.
Ferromanganese nodules of freshwater reservoirs of Ol’khon Island (Baikal) and the Kulunda Plain (West Siberia)
Russian Geology and Geophysics (2018) 59 (2): 123.
Pleistocene sediments of Lake Baikal: Lithology and stratigraphic correlation
Stratigraphy and Geological Correlation (2015) 23 (1): 94.
Geomicrobiology of Iron Layers in the Sediment of Lake Superior
Aquatic Geochemistry (2015) 21 (2-4): 123.
Composition and origin of the dolostones of Um Bogma Formation, Lower Carboniferous, West Central Sinai, Egypt
Carbonates and Evaporites (2014) 29 (3): 239.
Rare earth elements in the sediments of Lake Baikal
Chemical Geology (2014) 376: 61.
New insights into the formation and burial of Fe/Mn accumulations in Lake Baikal sediments
Chemical Geology (2012) 330-331: 244.
A new perspective on evolution of the Baikal Rift
Geoscience Frontiers (2011) 2 (3): 349.
Close Modal

or Create an Account

Close Modal
Close Modal