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Published November 04, 2016
A new study providing an unprecedented regional view of the earth’s crust beneath Yellowstone National Park will begin with a helicopter electromagnetic and magnetic (HEM) survey with a SkyTEM system Monday, Nov. 7.
Scientists from the U.S. Geological Survey, University of Wyoming and Aarhus University in Denmark hope to distinguish zones of cold fresh water, hot saline water, steam, clay and unaltered rock from one another to understand Yellowstone’s myriad hydrothermal systems. The flights will continue for the next two to four weeks.
Although the park’s iconic hydrothermal systems are well mapped at the surface, their subsurface groundwater flow systems are almost completely unknown. The HEM survey, operated by SkyTEM, will provide the first subsurface view of Yellowstone’s hydrothermal systems, tracking the geophysical signatures of geysers, hot springs, mud pots, steam vents and hydrothermal explosion craters to depths in excess of 1,000 feet.
A low-flying helicopter, about 200 feet above the ground’s surface, will fly along pre-planned flight grids focusing on the Mammoth-Norris corridor, Upper and Lower Geyser Basins, and the northern part of Yellowstone Lake. An electromagnetic system, resembling a giant hula hoop, will be suspended from the helicopter’s base. The equipment senses and records tiny voltages that can be related to the ground’s electrical conductivity.
These observations, combined with existing geophysical, geochemical, geological and borehole data, will help close a major knowledge gap between the surface hydrothermal systems and the deeper magmatic system. For example, research shows that the hot water spurting from Yellowstone’s geysers originates as old precipitation, snow and rain that percolates down into the crust, is heated and, ultimately, returns to the surface. This process takes hundreds if not thousands of years. Little, however, is currently known about the paths taken by the waters.
The data collected from the flight will guide future ground-based geological, hydrological and geophysical studies.
UW’s Wyoming Center for Environmental Hydrology and Geophysics (WyCEHG) is part of the research team. WyCEHG previously collaborated with Aarhus University, using SkyTEM, to map groundwater aquifers in the Laramie and Snowy ranges of southern Wyoming.