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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Canada
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Western Canada
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Alberta
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Banff National Park (1)
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United States
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Arkansas River (1)
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Arkansas River valley (1)
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Colorado (2)
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Western U.S. (1)
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elements, isotopes
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isotopes
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radioactive isotopes
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Be-10 (1)
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metals
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alkaline earth metals
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beryllium
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Be-10 (1)
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geochronology methods
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exposure age (1)
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tephrochronology (1)
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geologic age
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Cenozoic
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Quaternary
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Holocene
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upper Holocene (1)
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upper Quaternary
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Pinedale Glaciation (1)
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Tertiary
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Neogene
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Ogallala Formation (1)
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upper Cenozoic (1)
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Primary terms
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Canada
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Western Canada
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Alberta
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Banff National Park (1)
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Cenozoic
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Quaternary
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Holocene
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upper Holocene (1)
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upper Quaternary
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Pinedale Glaciation (1)
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Tertiary
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Neogene
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Ogallala Formation (1)
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upper Cenozoic (1)
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climate change (1)
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geochronology (2)
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geomorphology (1)
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isostasy (1)
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isotopes
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radioactive isotopes
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Be-10 (1)
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metals
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alkaline earth metals
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beryllium
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Be-10 (1)
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paleoclimatology (1)
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sedimentary structures
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planar bedding structures
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varves (1)
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sediments (1)
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tectonics
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neotectonics (1)
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United States
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Arkansas River (1)
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Arkansas River valley (1)
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Colorado (2)
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Western U.S. (1)
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sedimentary structures
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sedimentary structures
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planar bedding structures
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varves (1)
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sediments
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sediments (1)
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Abstract This field-trip guide outlines the glacial history of the upper Arkansas River valley, Colorado, and builds on a previous GSA field trip to the area in 2010. The following will be presented: (1) new cosmogenic 10 Be exposure ages of moraine boulders from the Pinedale and Bull Lake glaciations (Marine Isotope Stages 2 and 6, respectively) located adjacent to the Twin Lakes Reservoir, (2) numerical modeling of glaciers during the Pinedale glaciation in major tributaries draining into the upper Arkansas River, (3) discharge estimates for glacial-lake outburst floods in the upper Arkansas River valley, and (4) 10 Be ages on flood boulders deposited downvalley from the moraine sequences. This research was stimulated by a new geologic map of the Granite 7.5′ quadrangle, in which the mapping of surficial deposits was revised based in part on the interpretation of newly acquired LiDAR data and field investigations. The new 10 Be ages of the Pinedale terminal moraine at Twin Lakes average 21.8 ± 0.7 ka ( n = 14), which adds to nearby Pinedale terminal moraine ages of 23.6 ± 1.4 ka ( n = 5), 20.5 ± 0.2 ka ( n = 3), and 16.6 ± 1.0 ka ( n = 7), and downvalley outburst flood terraces that date to 20.9 ± 0.9 ka ( n = 4) and 19.0 ± 0.6 ka ( n = 4). This growing chronology leads to improved understanding of the controls and timing of glaciation in the western United States, the modeling of glacial-lake outburst flooding, and the reconstruction of paleotemperature through glacier modeling.
Assessing climatic and nonclimatic forcing of Pinedale glaciation and deglaciation in the western United States
Geomorphic and tectonic forcing of late Cenozoic warping of the Colorado piedmont
Abstract The central Colorado landscape bears a strong imprint of post-Laramide (late Eocene to Quaternary) tectonics, volcanism, climate change, and drainage rearrangement. This field trip will examine the post-Laramide evolution of central Colorado, traversing the Front Range, from the Colorado Piedmont on the east to the upper Arkansas valley segment of the Rio Grande Rift on the west (Fig. 1 ). The first day of the trip will involve a transect from the Denver-Colorado Springs section of the Piedmont across the southern Front Range, South Park, and Mosquito Range to the upper Arkansas valley. On this day we will focus on questions concerning the roles of tectonics and climate in driving post-Laramide landscape changes, examining structural, sedimentological, paleontological, geomorphic, and fission track evidence that has been used to reconstruct post-Laramide history. We will end the day with an initial overview of rift-related structures, sediments, and geomorphology as we enter the upper Arkansas valley. We will spend the second day in the southern portion of the upper Arkansas valley and the adjacent Poncha Pass transfer zone, examining structural and sedimentological evidence for the nature and timing of Neogene and Quaternary faulting and graben formation, and the character of the transfer zone. On our final day we will traverse back to the Piedmont, this time traveling down the canyons of the Arkansas River. We will examine rift-related structures and sediments in the Pleasant Valley graben and at the northern end of the Wet Mountain Valley, and will discuss the history of Cenozoic and earlier faulting in the area, the evolution of the Arkansas River drainage, and its recent downcutting history. We will end the trip with a discussion of the Neogene and Quaternary erosional history of the High Plains and Piedmont, and possible implications of this history for the driving mechanisms of landscape change.
A varve-based calibration of the Bridge River tephra fall
The Garden of the Gods and basal Phanerozoic nonconformity in and near Colorado Springs, Colorado
Abstract The Garden of the Gods, a city park within the Colorado Springs city limits, is located on the eastern flank of the Colorado Front Range (Fig. 1). It can be reached by following the Garden of the Gods Road (exit 146 from I-25) west 2.4 mi (3.8 km) until it curves to the south and becomes 30th Street. Continue south 1.5 mi (2.4 km) to an unnamed road marked by a small sign (Garden of the Gods) and turn right (west) into the park. Mesa Road, which veers uphill from 30th Street 0.8 mi (1.3 km) north of the turnoff to the park, crests at a spectacular overview of the park and surrounding areas. Several U.S. Geological Survey 7½-minute quadrangle maps cover this region. The Garden of the Gods lies mostly within the Pikeview and Cascade Quadrangles; with its southern part in the Colorado Springs and Manitou Springs Quadrangles. The two stops described here are all on public land and can be reached by passenger car.