"Lake Baikal is a unique, nearly pristine environment for the study of global change. Nowhere else in the world can we go to study so long a record of such an important, but little known, part of the global climate system."
The special environmental and geological settings of Lake Baikal provide unparalleled opportunities for research and for inter-national cooperation.
Lake Baikal is to Russia what the Grand Canyon is to the United States: a magnificent natural resource that instills national pride and awe. The Presidents of the United States and the Russian Federation recognized the uniqueness of Lake Baikal. In a recent Joint Statement, they affirm the need to conserve the environment of Lake Baikal and to use its potential for research in limnology, geology, and global climate change. The U.S. Geological Survey's (USGS) Office of Energy and Marine Geology and Office of International Geology, supported by the Coastal Geology Program and the Global Change and Climate History Program, are involved in broad collaborative programs to study Lake Baikal with the Russian Academy of Sciences and with a number of American universities through the (U.S.) National Science Foundation.
Understanding the origin of the Lake Baikal rift contributes to understanding one of the fundamental phenomena by which the history of the Earth is reconstructed.
Continental rifts, like the Lake Baikal rift, and their end products, such as passive continental margins like the east coast of the United States, are ubiquitous in the Earth's geologic record. They contain information from which a significant amount of the Earth's history has been interpreted. Due to their high sedimentation rates, large rift lakes like Lake Baikal have great potential for providing high-resolution information about both tectonic and climatic change. Significantly, sedimentary deposits of continental rifts are also associated with many of the Earth's hydrocarbon and mineral deposits.
USGS and Russian cooperative studies have begun to resolve the three-dimensional geometry of the Lake Baikal rift.
Sediments of Lake Baikal reach thicknesses in excess of 7 kilometers (4 miles), and the rift floor is perhaps 8 to 9 kilometers (more than 5 miles) deep, making it one of the deepest active rifts on Earth. The shallowest sediments may contain the only known freshwater occurrence of natural gas hydrates. Maps of complex fault patterns and changing depositional environments provide the first opportunities to describe the development of the lake and to help explain its unique flora and fauna.
Unique characteristics of the Lake Baikal environment combine to produce an especially promising site for studies of climate history.
Lake Baikal is the largest freshwater lake on Earth containing 23,000 cubic kilometers of water, or roughly 20 percent of the world's total surface fresh water. It contains as much fresh water as the Great Lakes of North America combined. At over 1,600 meters (5250 feet), it is the deepest lake in the world, and at perhaps more than 25 million years old, the oldest as well. The water of Lake Baikal is so fresh that calcium carbonate does not survive in the fossil record. Despite the lake's great depth , its water is well-oxygenated throughout creating unique biological habitats.
The high latitude of Lake Baikal makes it particularly sensitive to climatic variations.
Climate variations, including those resulting from atmospheric accumulation of carbon dioxide, are more pronounced at higher latitudes. Although the lake contains a record of glaciation of surrounding mountains in its sediments, it is unique among large, high-latitude lakes in that its sediments have not been scoured by overriding continental ice sheets.
United States and Russian studies of sediment cores taken from Lake Baikal provide a detailed record of climatic variation over the past 250,000 years.
Much attention is focused on numerical models of climate change but there have been few means for reliably testing or modifying boundary conditions of general circulation models. Studies of sedimentary environments in Lake Baikal provide important opportunities to establish ground truth for general circulation models. Very little data exist for long-term climate change from continental interiors; most of the data record derives from the marine or maritime environments. Finally, studies of past environments contribute to understanding the extent to which human activity affects natural conditions in the lake.
Seismic and sediment core analyses are used to fix future drilling sites in Lake Baikal.
Ice-based drilling operations begun in early 1993 are providing longer (over 100 meters in length) cores of Baikal sediments. Analyses of these cores are expected to reveal the climatic, environmental, and geological history of the region as far back as 5 million years. Seismic data will be tied to cores and drill samples to estimate rates of climate change and to map the history of the lake and rift. Very deep drilling in Lake Baikal remains technologically challenging; therefore, the deepest deposits of the rift are not likely to be sampled soon. However, the potentially very long record of sedimentation in Lake Baikal provides unique opportunities to understand the Cenozoic climate history of the Earth and to describe how continents begin to break apart, giving rise to new ocean basins.