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Bakers Bridge Granite

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Journal Article

Monazite and xenotime petrochronologic constraints on four Proterozoic tectonic episodes and ca. 1705 Ma age of the Uncompahgre Formation, southwestern Colorado, USA

Ian W. Hillenbrand, Michael L. Williams, Karl E. Karlstrom, Amy K. Gilmer, Heather A. Lowers, Michael J. Jercinovic, Kaitlyn A. Suarez, A. Kate Souders
Journal: Geosphere
Published: 23 June 2023
Geosphere (2023) 19 (4): 1057–1079.
DOI: https://doi.org/10.1130/GES02631.1
... and temperatures of 270 °C to >570 °C at 1470–1400 Ma. Laser ablation–inductively coupled plasma–mass spectrometry (LA-ICP-MS) zircon geochronology yielded dates of 1775 ± 18 Ma from the Twilight Gneiss and 1696 ± 7 Ma from the Bakers Bridge Granite, supporting previous isotope dilution–thermal ionization mass...
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Book Chapter

Proterozoic geology of the Needle Mountains; A summary

Author(s)
Barbara J. Tewksbury
Book: Proterozoic Geology of the Southern Rocky Mountains
Publisher: Geological Society of America
Published: 01 January 1989
DOI: 10.1130/SPE235-p65
... 1,760 Ma and were multiply deformed and metamorphosed shortly after accumulation. Small post-tectonic plutons of the Tenmile and Bakers Bridge Granites invaded the metavolcanic sequence between 1,680 and 1,700 Ma. The timing of deposition of the conglomerates, clean quartzites, and pelites...
Abstract
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The Early and Middle Proterozoic rocks in the Needle Mountains include three distinct rock sequences (1) multiply deformed bimodal metavolcanic rocks, related sedimentary rocks, and plutonio units, all metamorphosed to medium grade; (2) multiply deformed clastic sedimentary rocks metamorphosed to low grade; and (3) weakly foliated to unfoliated plutonic rocks. Although many important questions remain unresolved, work by a number of individuals suggests the following history. Mafic and silicic volcanics, sediments, and intrusives of the Irving Formation and Twilight Gneiss accumulated at least 1,760 Ma and were multiply deformed and metamorphosed shortly after accumulation. Small post-tectonic plutons of the Tenmile and Bakers Bridge Granites invaded the metavolcanic sequence between 1,680 and 1,700 Ma. The timing of deposition of the conglomerates, clean quartzites, and pelites of the Vallecito Conglomerate and the Uncompahgre Formation with respect to events in the metavolcanic sequence is poorly constrained, largely because shear zones lie along crucial contacts. Recent work suggests that much if not all of this clastic sedimentary sequence may be parautochthonous and was probably deposited sometime after 1,680 to 1,700 Ma. Despite uncertainties in timing of deposition, it is clear that a second event of deformation and metamorphism affected the region, producing polyphase features in both the metavolcanic sequence and the clastic sedimentary sequence, as well as a weak foliation in the Tenmile Granite. The Eolus Granite and related intrusions, ranging in age from 1,320 to 1,450 Ma, crosscut all structural features in the region and provide a minimum age limit for the latest deformation in the region. This younger event is recorded nowhere else in Colorado but may correlate with events in northern New Mexico.

Image
Tamarron Member at stratotype (locality A [Bakers Bridge]). G = granite. The dashed line identifies the nonconformity between the basement and the Ignacio Quartzite. The section is composed chiefly of estuarine sand-flat deposits.

Tamarron Member at stratotype (locality A [Bakers Bridge]). G = granite. Th...

Published: 01 December 2016
Figure 4. Tamarron Member at stratotype (locality A [Bakers Bridge]). G = granite. The dashed line identifies the nonconformity between the basement and the Ignacio Quartzite. The section is composed chiefly of estuarine sand-flat deposits.
Image

Major, trace, and isotope analyses of eight McDermott (McD), four La Plata,...

Published: 01 January 2011
Table 1. Major, trace, and isotope analyses of eight McDermott (McD), four La Plata, Baker's Bridge Granite (BBG), and the three Twilight Gneiss (TG) analyses. XRF analyses are in bold and ICP analyses in normal font. The TAS classification for the McDermott and La Plata samples are listed
Image
A, Spider diagram showing the similarities between incompatible trace element concentrations of McDermott trachyandesite, La Plata intrusives, and the Four Corners lower crustal xenolith average (Condie and Selverstone, 1999). B, Spider diagram showing the trends for the Twilight Gneiss and Baker's Bridge Granite in relation to the McDermott Formation. Compositions in both plots are normalized to primitive mantle values of McDonough and Sun (1995).

A , Spider diagram showing the similarities between incompatible trace ele...

Published: 01 January 2011
for the Twilight Gneiss and Baker's Bridge Granite in relation to the McDermott Formation. Compositions in both plots are normalized to primitive mantle values of McDonough and Sun (1995) .
Image
Photographs of outcrops and hand samples. (A) Hand sample of gneiss sample 21IWH07 from the western Needle Mountains. (B) Photograph of sample 21IWH18 from drill core PVTG3-2015 at the 443–444 m depth interval. (C) Hand sample of Vallecito Conglomerate mica-rich quartzite sample 21IWH05. (D) Outcrop photograph of Uncompahgre Formation sample 21IWH11. (E) Outcrop of leucocratic gneiss and hornblende-rich schist of the Twilight Gneiss at sample locality 21IWH03. (F) Outcrop of Bakers Bridge Granite, sample locality 21IWH04. (G) Hand sample of Eolus Granite float collected as sample 21IWH06. (H) Outcrop of granite at Cataract Gulch, sample locality 21AG06.

Photographs of outcrops and hand samples. (A) Hand sample of gneiss sample ...

Published: 23 June 2023
. (D) Outcrop photograph of Uncompahgre Formation sample 21IWH11. (E) Outcrop of leucocratic gneiss and hornblende-rich schist of the Twilight Gneiss at sample locality 21IWH03. (F) Outcrop of Bakers Bridge Granite, sample locality 21IWH04. (G) Hand sample of Eolus Granite float collected as sample
Image
Concordia and weighted mean diagrams for zircon laser ablation–inductively coupled plasma–mass spectrometry (LA-ICP-MS) data from samples: (A) 21IWH03 from the Twilight Gneiss, (B) 21IWH04 from the Bakers Bridge Granite, (C) 21IWH06 from the Eolus Granite, and (D) 21AG06 from the granite of Cataract Gulch. Data were visualized using IsoplotR (Vermeesch, 2018). Ellipses with dark outlines and gray fill represent data that passed concordance filters and were included in date calculations and interpretations. Data points outlined in light gray and without fill did not pass concordance filters (see Methods section) and were excluded from interpretation.

Concordia and weighted mean diagrams for zircon laser ablation–inductively ...

Published: 23 June 2023
Figure 8. Concordia and weighted mean diagrams for zircon laser ablation–inductively coupled plasma–mass spectrometry (LA-ICP-MS) data from samples: (A) 21IWH03 from the Twilight Gneiss, (B) 21IWH04 from the Bakers Bridge Granite, (C) 21IWH06 from the Eolus Granite, and (D) 21AG06 from
Image
—Well bedded Ignacio quartzite overlying granite at Baker’s Bridge.

—Well bedded Ignacio quartzite overlying granite at Baker’s Bridge.

Published: 01 November 1957
Fig. 3. —Well bedded Ignacio quartzite overlying granite at Baker’s Bridge.
Image
—Ignacio quartzite and underlying non-foliated granite near Baker Bridge; height of outcrop is about 45 feet. Details of boxed area shown in Figure 4.

—Ignacio quartzite and underlying non-foliated granite near Baker Bridge; h...

Published: 01 August 1954
FIG. 3. —Ignacio quartzite and underlying non-foliated granite near Baker Bridge; height of outcrop is about 45 feet. Details of boxed area shown in Figure 4 .
Image
—Part of Baker Bridge outcrop showing beds of Ignacio quartzite intruded by granite. Note how bedding planes and joints have controlled intrusion.

—Part of Baker Bridge outcrop showing beds of Ignacio quartzite intruded by...

Published: 01 August 1954
FIG. 4. —Part of Baker Bridge outcrop showing beds of Ignacio quartzite intruded by granite. Note how bedding planes and joints have controlled intrusion.
Image
—Quartzite xenoliths (light-colored) in granite exposed in roadcut, U. S. Highway 550 about 1½ miles north of junction with Baker Bridge road.

—Quartzite xenoliths (light-colored) in granite exposed in roadcut, U. S. H...

Published: 01 August 1954
FIG. 7. —Quartzite xenoliths (light-colored) in granite exposed in roadcut, U. S. Highway 550 about 1½ miles north of junction with Baker Bridge road.
Image
—Hammer rests on rhyolite porphyry dike intruded into granite at Baker’s Bridge. Ignacio quartzite appears in upper third of photo. For gross relations, refer to the left side of Figure 3.

—Hammer rests on rhyolite porphyry dike intruded into granite at Baker’s Br...

Published: 01 November 1957
Fig. 4. —Hammer rests on rhyolite porphyry dike intruded into granite at Baker’s Bridge. Ignacio quartzite appears in upper third of photo. For gross relations, refer to the left side of Figure 3 .
Image
—Photomicrograph of Ignacio quartzite from bed 10 feet above granite contact near Baker Bridge; chiefly subrounded quartz grains. ×nicols, ×40. Photomicrograph by J. Anthony Denson, U. S. Geological Survey.

—Photomicrograph of Ignacio quartzite from bed 10 feet above granite contac...

Published: 01 August 1954
FIG. 5. —Photomicrograph of Ignacio quartzite from bed 10 feet above granite contact near Baker Bridge; chiefly subrounded quartz grains. ×nicols, ×40. Photomicrograph by J. Anthony Denson, U. S. Geological Survey.
Journal Article

Petrogenesis of the McDermott Formation trachyandesite, San Juan basin, Colorado and New Mexico

Daniel Wegert, Don F. Parker
Published: 01 January 2011
Rocky Mountain Geology (2011) 46 (2): 183–196.
DOI: https://doi.org/10.2113/gsrocky.46.2.183
...Table 1. Major, trace, and isotope analyses of eight McDermott (McD), four La Plata, Baker's Bridge Granite (BBG), and the three Twilight Gneiss (TG) analyses. XRF analyses are in bold and ICP analyses in normal font. The TAS classification for the McDermott and La Plata samples are listed...
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Journal Article

Age and Stratigraphic Relations of Ignacio Quartzite in Southwestern Colorado

Harley Barnes
Journal: AAPG Bulletin
Published: 01 August 1954
AAPG Bulletin (1954) 38 (8): 1780–1791.
DOI: https://doi.org/10.1306/5CEAE02E-16BB-11D7-8645000102C1865D
...FIG. 3. —Ignacio quartzite and underlying non-foliated granite near Baker Bridge; height of outcrop is about 45 feet. Details of boxed area shown in Figure 4 . ...
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Journal Article

Ignacio Quartzite of Southwestern Colorado

F. H. T. Rhodes, James H. Fisher
Journal: AAPG Bulletin
Published: 01 November 1957
AAPG Bulletin (1957) 41 (11): 2508–2518.
DOI: https://doi.org/10.1306/0BDA59B4-16BD-11D7-8645000102C1865D
...Fig. 3. —Well bedded Ignacio quartzite overlying granite at Baker’s Bridge. ...
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Journal Article

Older Rocks of Van Horn Region, Texas

Philip B. King
Journal: AAPG Bulletin
Published: 01 January 1940
AAPG Bulletin (1940) 24 (1): 143–156.
DOI: https://doi.org/10.1306/3D933198-16B1-11D7-8645000102C1865D
.... In the meantime, the writer plans to describe some features of the Permian rocks of the mountains in a paper in a later number of this Bulletin . Studies are also in progress on the Ordovician and other older Paleozoic rocks by Josiah Bridge and Edwin Kirk, and a résumé of their results will be published...
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Journal Article

Stratigraphy, petrography, and depositional history of the Ignacio Quartzite and McCracken Sandstone Member of the Elbert Formation, southwestern Colorado, U.S.A.

Earle F. McBride
Published: 01 December 2016
Rocky Mountain Geology (2016) 51 (2): 23–68.
DOI: https://doi.org/10.2113/gsrocky.51.2.23
...Figure 4. Tamarron Member at stratotype (locality A [Bakers Bridge]). G = granite. The dashed line identifies the nonconformity between the basement and the Ignacio Quartzite. The section is composed chiefly of estuarine sand-flat deposits. ...
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View PDF for article title, Stratigraphy, petrography, and depositional history of the Ignacio Quartzite and McCracken Sandstone Member of the Elbert Formation, southwestern Colorado, U.S.A.
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Journal Article

Highway Performance during the 16 October 1999 Hector Mine, California, Earthquake

Mark Yashinsky, Jaro Simek, Ganapathy Murugesh, Lalliana Mualchin
Published: 01 May 2002
Bulletin of the Seismological Society of America (2002) 92 (4): 1621–1632.
DOI: https://doi.org/10.1785/0120000904
...Mark Yashinsky; Jaro Simek; Ganapathy Murugesh; Lalliana Mualchin Abstract The M 7.1 Hector Mine earthquake caused little bridge or highway damage. Although it seems reasonable to assume that the lack of damage was the result of the earthquake occurring in the middle of the desert, there were...
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Journal Article

A review of analogues of alkaline alteration with regard to long-term barrier performance

D. Savage
Published: 01 August 2011
Mineralogical Magazine (2011) 75 (4): 2401–2418.
DOI: https://doi.org/10.1180/minmag.2011.075.4.2401
..., sandstone Alkali-silica gel lining pores, with K-, Na-substituted okenite in reaction rims on aggregate grains ( Cole et al. , 1981 ); ( Cole and Lancucki, 1983 ) Dam walls, bridge 15–50 Granites; alluvial sediment Alkali-silica gel in reaction rims on aggregate grains 1 mm reaction rims...
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