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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Corpus Christi Bay (1)
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North America
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Gulf Coastal Plain (1)
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United States
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Colorado
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Denver County Colorado
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Denver Colorado (1)
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Texas
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Nueces River (1)
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elements, isotopes
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isotopes
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radioactive isotopes
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Rn-222 (2)
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noble gases
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radon
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Rn-222 (2)
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fossils
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Invertebrata
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Mollusca (1)
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geologic age
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Cenozoic
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Quaternary
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upper Quaternary (1)
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Primary terms
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Cenozoic
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Quaternary
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upper Quaternary (1)
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geophysical methods (1)
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Invertebrata
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Mollusca (1)
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isotopes
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radioactive isotopes
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Rn-222 (2)
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noble gases
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radon
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Rn-222 (2)
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North America
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Gulf Coastal Plain (1)
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pollution (2)
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sedimentation (1)
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sediments
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clastic sediments
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clay (1)
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soils (2)
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stratigraphy (1)
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United States
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Colorado
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Denver County Colorado
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Denver Colorado (1)
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Texas
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Nueces River (1)
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sediments
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sediments
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clastic sediments
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clay (1)
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soils
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soils (2)
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Geology of radon in the United States
More than one-third of the United States is estimated to have high geologic radon potential. A high radon potential area is defined as an area in which the average indoor radon screening measurement is expected to be 4 pCi/L or greater. Geologic terrains of the United States with high radon potential include: 1. Uraniferous metamorphosed sediments, volcanics, and granite intrusives that are highly deformed and often sheared. Shear zones in these rocks cause the highest indoor radon problems in the United States. 2. Glacial deposits derived from uranium-bearing rocks and sediments and glacial lake deposits. Clay-rich tills and lake clays have high radon emanation because of high specific surface area and high permeability due to desiccation cracking when dry. 3. Marine black shales. The majority of black shales are moderately uraniferous and have high emanation coefficients and high fracture permeability. 4. Soils derived from carbonate, especially in karstic terrain. Although most carbonates are low in uranium, the soils derived from them are very high in uranium and radium. 5. Uraniferous fluvial, deltaic, marine, and lacustrine deposits. Much of the nation’s reserve uranium ores are contained within these sedimentary deposits, which dominate the stratigraphy of the western U.S.
Effects of weather and soil characteristics on temporal variations in soil-gas radon concentrations
Concentrations of radon-222 in soil gas measured over about 1 yr at a monitoring site in Denver, Colorado, vary by as much as an order of magnitude seasonally and as much as severalfold in response to changes in weather. The primary weather factors that influence soil-gas radon concentrations are precipitation and barometric pressure. Soil characteristics are important in determining the magnitude and extent of the soil’s response to weather changes. The soil at the study site is clay rich and develops desiccation cracks upon drying that increase the soil’s permeability and enhance gas transport and removal of radon from the soil. A capping effect caused by frozen or unfrozen soil moisture is a primary mechanism for preventing radon loss to the atmosphere.