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Journal Article

Alluvial-fan sedimentation of the Cutler Formation (Permo-Pennsylvanian) near Gateway, Colorado Available to Purchase

GREG H. MACK, KEITH A. RASMUSSEN
Journal: GSA Bulletin
Published: 01 January 1984
GSA Bulletin (1984) 95 (1): 109–116.
DOI: https://doi.org/10.1130/0016-7606(1984)95<109:ASOTCF>2.0.CO;2
...GREG H. MACK; KEITH A. RASMUSSEN Abstract The Permo-Pennsylvanian Cutler Formation near Gateway, Colorado, is the most complete (1,334 m) proximal section of alluvial-fan sediments deposited along the western flank of the Ancestral Uncompahgre uplift. Cutler facies can be correlated...
View PDF for article title, Alluvial-fan sedimentation of the Cutler Formation (Permo-Pennsylvanian) near <span class="search-highlight">Gateway</span>, <span class="search-highlight">Colorado</span>
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Journal Article

Petrology of the Cutler Formation (Pennsylvanian-Permian) near Gateway, Colorado, and Fisher Towers, Utah Available to Purchase

William G. Werner
Published: 01 June 1974
Journal of Sedimentary Research (1974) 44 (2): 292–298.
DOI: https://doi.org/10.1306/74D72A18-2B21-11D7-8648000102C1865D
...William G. Werner Abstract The Cutler Formation (Pennsylvanian-Permian) of the northwestern Colorado Plateau was deposited as an alluvial fan complex along the western margin of the ancestral Uncompahgre Uplift. Near Gateway, Colorado, and Fisher Towers, Utah, the Cutler comprises rapidly-deposited...
View PDF for article title, Petrology of the Cutler Formation (Pennsylvanian-Permian) near <span class="search-highlight">Gateway</span>, <span class="search-highlight">Colorado</span>, and Fisher Towers, Utah
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Journal Article

Mesaite, Ca (V 2 O 7 ) 3 ·12H 2 O, a new vanadate mineral from the Packrat mine, near Gateway, Mesa County, Colorado, USA Available to Purchase

Anthony R. Kampf, Barbara P. Nash, Joe Marty, John M. Hughes
Published: 01 April 2017
Mineralogical Magazine (2017) 81 (2): 319–327.
DOI: https://doi.org/10.1180/minmag.2016.080.095
...Anthony R. Kampf; Barbara P. Nash; Joe Marty; John M. Hughes Abstract Mesaite (IMA2015-069), ideally Ca (V 2 O 7 ) 3 ·12H 2 O, is a new mineral from the Packrat mine, Gateway district, Mesa County, Colorado, USA. Crystals of mesaite occur as orangish red blades up to 0.1 mm long and ∼10 μm thick...
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View PDF for article title, Mesaite, Ca (V 2 O 7 ) 3 ·12H 2 O, a new vanadate mineral from the Packrat mine, near <span class="search-highlight">Gateway</span>, Mesa County, <span class="search-highlight">Colorado</span>, USA
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Image

Climatic information from the Cutler Formation near Gateway, Colorado. Available to Purchase

Published: 01 July 2009
Table 6 Climatic information from the Cutler Formation near Gateway, Colorado.
Journal Article

Geology of Unaweep Canyon and its role in the drainage evolution of the northern Colorado Plateau Open Access

Gerilyn S. Soreghan, Dustin E. Sweet, Stuart N. Thomson, Sara A. Kaplan, Kristen R. Marra, Greg Balco, Thaddeus M. Eccles
Journal: Geosphere
Published: 01 April 2015
Geosphere (2015) 11 (2): 320–341.
DOI: https://doi.org/10.1130/GES01112.1
... of Quaternary deposits in and near the canyon shed light on its late Cenozoic history, and call into question whether the canyon was incised by a Cenozoic river, or merely exhumed by one. Gravels near the western mouth of Unaweep Canyon (Gateway, Colorado) exhibit a distinctive intermediate volcanic provenance...
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View PDF for article title, Geology of Unaweep Canyon and its role in the drainage evolution of the northern <span class="search-highlight">Colorado</span> Plateau
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Book Chapter

River incision histories of the Black Canyon of the Gunnison and Unaweep Canyon: Interplay between late Cenozoic tectonism, climate change, and drainage integration in the western Rocky Mountains Available to Purchase

Author(s)
Andres Aslan, Karl Karlstrom, William C. Hood, Rex D. Cole, Thomas W. Oesleby, Charles Betton, M. Magdalena Sandoval, Andy Darling, Sam Kelley, Adam Hudson, Bryan Kaproth, Shane Schoepfer, Mary Benage, Rachel Landman
Book: Roaming the Rocky Mountains and Environs: Geological Field Trips
Series: GSA Field Guide
Publisher: Geological Society of America
Published: 01 January 2008
DOI: 10.1130/2007.fld010(09)
EISBN: 9780813756103
... Gateway, Colorado. The average gradient of the ancestral Gunnison River through the canyon prior to abandonment was ~7.5–7.6 m/km. Lithological and mineralogical considerations suggest that the Colorado River also flowed through and helped to carve Unaweep Canyon, although the Colorado River probably...
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Abstract
View PDF for content titled, River incision histories of the Black Canyon of the Gunnison and Unaweep Canyon: Interplay between late Cenozoic tectonism, climate change, and drainage integration in the western Rocky Mountains
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Abstract The Black Canyon of the Gunnison and Unaweep Canyon in western Colorado have long been viewed as classic examples of post-Laramide Plio-Pleistocene uplift, which in the case of Unaweep, is thought to have forced the Gunnison River to abandon the canyon. Ongoing field studies of the incision histories of these canyons and their surrounding regions, however, suggest that post-Laramide rock uplift has been regional, rather than local in nature. River incision rates calculated using ca. 10 Ma basaltic lava flows as a late Miocene datum suggest that long-term incision rates range from 61 to 142 m/m.y. with rates decreasing eastward towards the central Rocky Mountains. Incision rates calculated using the ca. 640 ka Lava Creek B ash range from 95 to 162 m/m.y., decrease eastward towards the mountains, and are broadly similar in magnitude to the longer-term incision rates. Locally, incision rates are as high as 500–600 m/m.y. along the lower reaches of the Black Canyon of the Gunnison, and these anomalously high values reflect transient knickpoint migration upvalley. Knickpoint migration was controlled, in part, by downvalley base-level changes related to stream piracy. For example, abandonment of Unaweep Canyon by the Gunnison River could have led to rapid incision through erodible Mancos Shale as the Gunnison River joined the Colorado River on its course around the northern end of the Uncompahgre Plateau. Geophysical data show that abandonment of Unaweep Canyon was not caused by differential uplift of the crest of Unaweep Canyon relative to the surrounding basins. Instead, the ancestral (Plio-Pleistocene?) Gunnison River flowed through Cactus Park, a major paleovalley that feeds into Unaweep Canyon, and continued downvalley to its juncture with the Dolores River near present-day Gateway, Colorado. The average gradient of the ancestral Gunnison River through the canyon prior to abandonment was ~7.5–7.6 m/km. Lithological and mineralogical considerations suggest that the Colorado River also flowed through and helped to carve Unaweep Canyon, although the Colorado River probably exited Unaweep Canyon prior to abandonment by the Gunnison River. The ancestral Gunnison River remained in its course and incised through bedrock for a long enough period of time to produce terrace remnants in the Cactus Park region that range in elevation from 2000 to 1880 m. Abandonment of the canyon by the Gunnison River was followed by formation of a natural dam that probably led to deposition upvalley of ~50 m of lacustrine sediments in Cactus Park. Recent mapping in the lower reaches of Unaweep Canyon indicate that a landslide could have led to damming of Unaweep Canyon, perhaps while it was occupied by underfit streams.

Journal Article

Regional Influence of Tectonics on Uranium Occurrences in Colorado Plateau Area: ABSTRACT Free

Y. William Isachsen
Journal: AAPG Bulletin
Published: 01 April 1956
AAPG Bulletin (1956) 40 (4): 793–794.
DOI: https://doi.org/10.1306/5CEAE451-16BB-11D7-8645000102C1865D
...Y. William Isachsen ABSTRACT Most uranium deposits of the Colorado Plateau are restricted to lenticular sandstones and conglomerates, and are characterized by relatively obvious local sedimentary controls. An argument can be made, however, that the areal and regional controls of uranium deposition...
View PDF for article title, Regional Influence of Tectonics on Uranium Occurrences in <span class="search-highlight">Colorado</span> Plateau Area: ABSTRACT
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Journal Article

Subaerial debris-flow deposition in the upper Paleozoic Cutler Formation, western Colorado Available to Purchase

Albert W. Shultz
Published: 01 September 1984
Journal of Sedimentary Research (1984) 54 (3): 759–772.
DOI: https://doi.org/10.1306/212F84EF-2B24-11D7-8648000102C1865D
...Albert W. Shultz Abstract Outcrops of the lower part of the Cutler Formation near Gateway, Colorado, contain proximal alluvial-fan deposits of two principal lithofacies. The diamictite lithofacies (D) consists of a variety of sharply bounded, massive, muddy beds which are interpreted as deposits...
View PDF for article title, Subaerial debris-flow deposition in the upper Paleozoic Cutler Formation, western <span class="search-highlight">Colorado</span>
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Image
Pennsylvanian–Early Permian stratigraphy of the Cutler Formation study region (near Gateway, Colorado), after Sweet and Soreghan (2010a).

Pennsylvanian–Early Permian stratigraphy of the Cutler Formation study regi... Available to Purchase

Published: 01 November 2015
Fig. 2.— Pennsylvanian–Early Permian stratigraphy of the Cutler Formation study region (near Gateway, Colorado), after Sweet and Soreghan (2010a) .
Image
Photos of gravel units. (A) Gateway gravels, characterized by well-rounded clasts of large Precambrian and smaller intermediate volcanic and sedimentary clasts. (B) Close-up of an intermediate volcanic clast in the Gateway gravels. Pen for scale. (C) Contact between the Gateway gravels (hammer handle) and overlying Palisade gravels (hammer head). (D) Close-up of the Palisade gravels; note clast angularity and the red color. Pen for scale. (E) Vertical cliff faces and hoodoos of the Palisade gravels. (F) West Creek gravels exposed along Highway 141 near Gateway, Colorado. Note strath carved into the Cutler Formation exposed at lower left.

Photos of gravel units. (A) Gateway gravels, characterized by well-rounded ... Open Access

Published: 01 April 2015
(hammer handle) and overlying Palisade gravels (hammer head). (D) Close-up of the Palisade gravels; note clast angularity and the red color. Pen for scale. (E) Vertical cliff faces and hoodoos of the Palisade gravels. (F) West Creek gravels exposed along Highway 141 near Gateway, Colorado. Note strath
Image
Digital elevation model (30 m base) of the Uncompahgre Plateau extending from Whitewater (northeast) to Gateway, Colorado (southwest). Locations of Unaweep Canyon, Cactus Park, and important sample sites are shown. OK core—University of Oklahoma drillhole (Marra et al., 2008). The 22 Ma apatite fission track (AFT) cooling age at Unaweep Divide is from a sample of Taylor Ranch granite sampled at an elevation of 2130 m; 38 Ma AFT cooling age near Gateway is from a sample of Vernal Mesa granite sampled at an elevation of 1550 m. Location of Figure 6 is also shown.

Digital elevation model (30 m base) of the Uncompahgre Plateau extending fr... Open Access

Published: 01 June 2014
Figure 3. Digital elevation model (30 m base) of the Uncompahgre Plateau extending from Whitewater (northeast) to Gateway, Colorado (southwest). Locations of Unaweep Canyon, Cactus Park, and important sample sites are shown. OK core—University of Oklahoma drillhole ( Marra et al., 2008 ). The 22
Image
A) Line drawing of the relationship between the Uncompahgre uplift, Unaweep Canyon, and the Cutler Formation near Gateway, Colorado. B) Detailed location map illustrating measured section locations (III through XII, shown in Fig. 4), sample locations (black dots, Fig. 4), and facies associations (of Soreghan et al. 2009a).

A) Line drawing of the relationship between the Uncompahgre uplift, Unawee... Available to Purchase

Published: 01 November 2015
Fig. 3.— A) Line drawing of the relationship between the Uncompahgre uplift, Unaweep Canyon, and the Cutler Formation near Gateway, Colorado. B) Detailed location map illustrating measured section locations (III through XII, shown in Fig. 4), sample locations (black dots, Fig. 4), and facies
Image
(A) Geological cross section showing Laramide structural relief and faulting. The line of section parallels Unaweep Canyon between Whitewater and Gateway, Colorado (modified from Aslan et al., 2008a). (B) Thermal history plot for the apatite fission track (AFT) samples at Unaweep Divide (07UNI01, blue) and near Gateway (07UNI02, red). Geological constraints for the models depicted by the solid lines are: (1) the basement was near the surface ca. 100 Ma at the time of Dakota Sandstone deposition; (2) the area attained maximum burial ca. 66 Ma at the end of Cretaceous Mesaverde Group deposition; (3) the basement is now at 11 °C. Only constraint 3 was used for the models depicted by the dashed lines. See text for further discussion. PAZ—partial annealing zone.

(A) Geological cross section showing Laramide structural relief and faultin... Open Access

Published: 01 June 2014
Figure 4. (A) Geological cross section showing Laramide structural relief and faulting. The line of section parallels Unaweep Canyon between Whitewater and Gateway, Colorado (modified from Aslan et al., 2008a ). (B) Thermal history plot for the apatite fission track (AFT) samples at Unaweep
Image
Stacked normalized probability-density plot of U-Pb detrital zircon spectra for samples from the modern Gunnison, Uncompahgre, and Colorado Rivers, and ancient fluvial sands from the Cactus Park gravel pit and a recent backhoe exposure at Gateway, Colorado (see Fig. 3). Data are shown only for grains younger than 600 Ma to highlight major differences among the samples. Numbers represent the age of peaks and N is number of grains analyzed. Note that the modern rivers were sampled upstream of their confluence with one another. See text for further discussion. All the U-Pb zircon ages for each of the samples are contained in Supplemental Table 1 (see footnote 1).

Stacked normalized probability-density plot of U-Pb detrital zircon spectra... Open Access

Published: 01 June 2014
Figure 9. Stacked normalized probability-density plot of U-Pb detrital zircon spectra for samples from the modern Gunnison, Uncompahgre, and Colorado Rivers, and ancient fluvial sands from the Cactus Park gravel pit and a recent backhoe exposure at Gateway, Colorado (see Fig. 3 ). Data are shown
Image
A) Early Permian paleogeographic map of the Uncompahgre and proximal alluvial and fluvial system. Line a–a′ parallels West Creek near the town of Gateway, Colorado. B) Stratigraphic schematic cross section at the time of deposition of the MGSF-bearing strata. More proximal strata are currently eroded but were assumed to have been similar to the exposed MGSF bearing strata. The heavier boldface line in the center of the section indicates the time surface at the end of lacustrine deposition. Cross section is adapted from Soreghan et al. (2009).

A) Early Permian paleogeographic map of the Uncompahgre and proximal alluv... Available to Purchase

Published: 01 August 2017
Figure 4 A) Early Permian paleogeographic map of the Uncompahgre and proximal alluvial and fluvial system. Line a–a′ parallels West Creek near the town of Gateway, Colorado. B) Stratigraphic schematic cross section at the time of deposition of the MGSF-bearing strata. More proximal strata
Image
Photographs and photomicrographs of the Cutler Formation at the Gateway, Colorado, study site. A) Stratigraphic succession of alluvial facies demonstrating interbedded MGSF (reddish-brown beds) and stream-flow facies (pink). Three white arrows show location of Parts B and C. B) Close-up of MGSF heavily scoured by overlying stream-flow facies. White arrows denote the base of the MGSF deposit. C) Close-up demonstrating the abrupt and relatively planar basal contact of MGSF denoted by the white arrows. D–F) a series of photomicrographs demonstrating the poor sorting and immature texture of the MGSF at a variety of scales. All three images are taken at the same place in the same thin section.

Photographs and photomicrographs of the Cutler Formation at the Gateway, Co... Available to Purchase

Published: 01 August 2017
Figure 8 Photographs and photomicrographs of the Cutler Formation at the Gateway, Colorado, study site. A) Stratigraphic succession of alluvial facies demonstrating interbedded MGSF (reddish-brown beds) and stream-flow facies (pink). Three white arrows show location of Parts B and C. B) Close
Image
Pennsylvanian–Early Permian stratigraphy in the Paradox basin from the distal southwestern margin (Four Corners region of Mexican Hat, Utah) through the proximal northeastern margin (study area of Gateway, Colorado), a distance of approximately 200 km (depicted as A–A′ in Fig. 1). Correlations shown are approximate only and lateral relationships are schematic. The study area is denoted by B–B′ (depicted in detail in Figs. 3 and 16). The time (relative and absolute) recorded by the Cutler Formation in the study area remains poorly known in detail, inasmuch as the only constraints derive from tentative correlations. Figure is modified from Barbeau (2003) and sources therein, and is based on data cited therein, and from Baars (1962), Molenaar (1987), Condon (1997), and a single detrital zircon date showing the lower Cutler beds (Mexican Hat region) to be as young as 283 ± 4 Ma (M. Soreghan et al. 2002). Absolute ages are from the Gradstein et al. (2004) timescale, with both International and North American stages depicted. Structural relationship depicted in the Gateway region is from Moore et al. (2008).

Pennsylvanian–Early Permian stratigraphy in the Paradox basin from the dist... Available to Purchase

Published: 01 July 2009
Figure 2 Pennsylvanian–Early Permian stratigraphy in the Paradox basin from the distal southwestern margin (Four Corners region of Mexican Hat, Utah) through the proximal northeastern margin (study area of Gateway, Colorado), a distance of approximately 200 km (depicted as A–A′ in Fig. 1
Image
Location map of western equatorial Pangaea during the Late Pennsylvanian–Early Permian, showing regions discussed in the text. A, Inset showing Pangaea, with detailed area of B denoted by the rectangle. B, Study area of the Ancestral Rocky Mountains, western United States. Paleouplifts are shown as shaded areas, whereas documented accumulations of upper Pennsylvanian–lower Permian (generalized) loessite accumulations are shown stippled. Geographic regions discussed in the text are as follows: Front Range uplift (FRU), Uncompahgre uplift (UU), Ute Pass uplift (UPU), Wichita uplift (WU), and Paradox basin (PB). The small rectangles indicate the study areas for the Cutler-Unaweep system near the towns of Gateway, Colorado (ga), and the Fountain Formation near Manitou Springs, Colorado (ms). Cross section A–A′ appears in figure 10. Loessite accumulations depicted for various sites are from the following publications: Arizona (Soreghan 1992; Soreghan et al. 2007a), Colorado (Johnson 1989; Tramp et al. 2004), New Mexico (Kessler et al. 2001), Oklahoma-Kansas (Dubois et al. 2012; Giles et al. 2013; Sweet et al. 2013; Foster et al. 2014), and Utah (Murphy 1987; Soreghan et al. 2002a).

Location map of western equatorial Pangaea during the Late Pennsylvanian–Ea... Available to Purchase

Published: 14 March 2014
uplift (WU), and Paradox basin (PB). The small rectangles indicate the study areas for the Cutler-Unaweep system near the towns of Gateway, Colorado (ga), and the Fountain Formation near Manitou Springs, Colorado (ms). Cross section A–A′ appears in figure 10 . Loessite accumulations depicted for various
Image
(A–C) Framework mineralogy point-count data for the Gateway gravels (black; location in Fig. 2), ancestral Gunnison gravels at Cactus Park (orange; location in Fig. 2), and ancestral Colorado River gravels upstream of the Colorado-Gunnison confluence (blue; location in Fig. 1; sampled from the QT3 [ca. 0.96 Ma] and QT4 [ca. 1.2 Ma] terraces of Carrara [2001]). Q—quartz, P—plagioclase, K—potassium feldspar, LvL—volcanic lithic with lathwork fabric, LvM—volcanic lithic with microlitic fabric, LvV—volcanic lithic with vitric fabric (for definitions of volcanic lithic fabrics, see Marsaglia, 1993). All are indistinguishable on the basis of quartz and feldspar alone. However, a clear distinction exists on the basis of the types of volcanic lithic fragments; the Gateway gravels show the strongest affiliation to the ancestral Gunnison gravels, rather than exhibiting a mixed signal, expected if they were deposited by a combined (ancestral) Gunnison-Colorado river. The relative ratios of microlitic-vitric volcanic lithics versus lathwork volcanic lithics is consistent with a predominant mafic volcanic (basaltic) source for the Colorado samples and a predominant intermediate volcanic (andesitic) source for the Cactus Park and Gateway (ancestral Gunnison) gravels (cf. Marsaglia, 1993).

(A–C) Framework mineralogy point-count data for the Gateway gravels (black;... Open Access

Published: 01 April 2015
Figure 9. (A–C) Framework mineralogy point-count data for the Gateway gravels (black; location in Fig. 2 ), ancestral Gunnison gravels at Cactus Park (orange; location in Fig. 2 ), and ancestral Colorado River gravels upstream of the Colorado-Gunnison confluence (blue; location in Fig. 1
Journal Article

Vanarsite, Packratite, Morrisonite, and Gatewayite: Four New Minerals Containing the [As 3+ V 4+,5+ 12 As 5+ 6 O 51 ] Heteropolyanion, a Novel Polyoxometalate Cluster Available to Purchase

Anthony R. Kampf, John M. Hughes, Barbara P. Nash, Joe Marty
Published: 01 January 2016
The Canadian Mineralogist (2016) 54 (1): 145–162.
DOI: https://doi.org/10.3749/canmin.1500062
... O 51 ) 2 ·78H 2 O, and gatewayite (IMA2014-096), Ca 6 (As 3+ V 4+ 3 V 5+ 9 As 5+ 6 O 51 )·31H 2 O, are four new minerals from the Packrat mine, Gateway district, Mesa County, Colorado, U.S.A. Crystals of all four new minerals are very dark blue to greenish-blue blades. They are found together...
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View PDF for article title, Vanarsite, Packratite, Morrisonite, and Gatewayite: Four New Minerals Containing the [As 3+ V 4+,5+ 12 As 5+ 6 O 51 ] Heteropolyanion, a Novel Polyoxometalate Cluster
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