1-20 OF 464 RESULTS FOR

Teton Range

Results shown limited to content with bounding coordinates.
Save search
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
Close Modal
Sort by
Journal Article

Postglacial slip-rate increase on the Teton normal fault, northern Basin and Range Province, caused by melting of the Yellowstone ice cap and deglaciation of the Teton Range? Available to Purchase

Andrea Hampel, Ralf Hetzel, Alexander L. Densmore
Journal: Geology
Published: 01 December 2007
Geology (2007) 35 (12): 1107–1110.
DOI: https://doi.org/10.1130/G24093A.1
...Andrea Hampel; Ralf Hetzel; Alexander L. Densmore Abstract Along the eastern front of the Teton Range, Wyoming, prominent fault scarps offset Pinedale deposits by up to 30 m and document that multiple earthquakes ruptured the range-bounding Teton normal fault after the last glacial period...
FIGURES
First thumbnail for: Postglacial slip-rate increase on the <span class=...
Second thumbnail for: Postglacial slip-rate increase on the <span class=...
Third thumbnail for: Postglacial slip-rate increase on the <span class=...
View PDF for article title, Postglacial slip-rate increase on the <span class="search-highlight">Teton</span> normal fault, northern Basin and <span class="search-highlight">Range</span> Province, caused by melting of the Yellowstone ice cap and deglaciation of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>?
Purchase
Add to Citation Manager for Postglacial slip-rate increase on the <span class="search-highlight">Teton</span> normal fault, northern Basin and <span class="search-highlight">Range</span> Province, caused by melting of the Yellowstone ice cap and deglaciation of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>?
Journal Article

Removal of the Northern Paleo-Teton Range along the Yellowstone Hotspot Track Open Access

Ryan Thigpen, Summer J. Brown, Autumn L. Helfrich, Rachel Hoar, Michael McGlue, Edward Woolery, William R. Guenthner, Meredith L. Swallom, Spencer Dixon, Sean Gallen
Journal: Lithosphere
Publisher: GSW
Published: 27 October 2021
Lithosphere (2021) 2021 (1): 1052819.
DOI: https://doi.org/10.2113/2021/1052819
... or more to completely remove tectonically generated relief. Here, we propose that mountain ranges can be completely and rapidly (<2 Myr) removed by a migrating hotspot. In western North America, multiple mountain ranges, including the Teton Range, terminate at the boundary with the relatively low...
FIGURES
First thumbnail for: Removal of the Northern Paleo-<span class="search-...
Second thumbnail for: Removal of the Northern Paleo-<span class="search-...
Third thumbnail for: Removal of the Northern Paleo-<span class="search-...
View PDF for article title, Removal of the Northern Paleo-<span class="search-highlight">Teton</span> <span class="search-highlight">Range</span> along the Yellowstone Hotspot Track
Add to Citation Manager for Removal of the Northern Paleo-<span class="search-highlight">Teton</span> <span class="search-highlight">Range</span> along the Yellowstone Hotspot Track
Journal Article

2.7 Ga high-pressure granulites of the Teton Range: Record of Neoarchean continent collision and exhumation Open Access

Susan M. Swapp, Carol D. Frost, B. Ronald Frost, D. Braden Fitz-Gerald
Journal: Geosphere
Published: 07 May 2018
Geosphere (2018) 14 (3): 1031–1050.
DOI: https://doi.org/10.1130/GES01607.1
... ability to understand how closely Archean tectonic processes may have resembled better-understood modern processes. Here we describe Neoarchean gneisses in the Teton Range of Wyoming, USA, that record 2.70 Ga high-pressure granulite facies metamorphism, followed by juxtaposition of gneisses with different...
FIGURES
First thumbnail for: 2.7 Ga high-pressure granulites of the <span class...
Second thumbnail for: 2.7 Ga high-pressure granulites of the <span class...
Third thumbnail for: 2.7 Ga high-pressure granulites of the <span class...
View PDF for article title, 2.7 Ga high-pressure granulites of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>: Record of Neoarchean continent collision and exhumation
Add to Citation Manager for 2.7 Ga high-pressure granulites of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>: Record of Neoarchean continent collision and exhumation
Includes: Supplemental Content
Journal Article

Neoarchean tectonic history of the Teton Range: Record of accretion against the present-day western margin of the Wyoming Province Open Access

B. Ronald Frost, Susan M. Swapp, Carol D. Frost, Davin A. Bagdonas, Kevin R. Chamberlain
Journal: Geosphere
Published: 11 April 2018
Geosphere (2018) 14 (3): 1008–1030.
DOI: https://doi.org/10.1130/GES01559.1
...B. Ronald Frost; Susan M. Swapp; Carol D. Frost; Davin A. Bagdonas; Kevin R. Chamberlain Abstract Although Archean gneisses of the Teton Range crop out over an area of only 50 × 15 km, they provide an important record of the Archean history of the Wyoming Province. The northern and southern parts...
FIGURES
First thumbnail for: Neoarchean tectonic history of the <span class="se...
Second thumbnail for: Neoarchean tectonic history of the <span class="se...
Third thumbnail for: Neoarchean tectonic history of the <span class="se...
View PDF for article title, Neoarchean tectonic history of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>: Record of accretion against the present-day western margin of the Wyoming Province
Add to Citation Manager for Neoarchean tectonic history of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>: Record of accretion against the present-day western margin of the Wyoming Province
Includes: Supplemental Content
Journal Article

Systematic variation of Late Pleistocene fault scarp height in the Teton Range, Wyoming, USA: Variable fault slip rates or variable landform ages? Open Access

Glenn D. Thackray, Amie E. Staley
Journal: Geosphere
Published: 01 April 2017
Geosphere (2017) 13 (2): 287–300.
DOI: https://doi.org/10.1130/GES01320.1
...Glenn D. Thackray; Amie E. Staley Abstract Fault scarps of strongly varying height cut glacial and alluvial sequences mantling the faulted front of the Teton Range (western USA). Scarp heights vary from 11.2 to 37.6 m and are systematically higher on geomorphically older landforms. Fault scarps...
FIGURES
First thumbnail for: Systematic variation of Late Pleistocene fault sca...
Second thumbnail for: Systematic variation of Late Pleistocene fault sca...
Third thumbnail for: Systematic variation of Late Pleistocene fault sca...
View PDF for article title, Systematic variation of Late Pleistocene fault scarp height in the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>, Wyoming, USA: Variable fault slip rates or variable landform ages?
Add to Citation Manager for Systematic variation of Late Pleistocene fault scarp height in the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>, Wyoming, USA: Variable fault slip rates or variable landform ages?
Journal Article

10 Be analysis of amalgamated talus pebbles to investigate alpine erosion, Garnet Canyon, Teton Range, Wyoming Open Access

Lisa M. Tranel, Meredith L. Strow
Journal: Geosphere
Published: 01 February 2017
Geosphere (2017) 13 (1): 36–48.
DOI: https://doi.org/10.1130/GES01297.1
... and catchment averaged erosion processes in the alpine setting of Garnet Canyon in the Teton Range, Wyoming, USA. We measured cosmogenic 10 Be concentrations from bedrock and talus deposits to compare them to volumetric estimates of erosion rates, lichen growth, and surface weathering on talus surfaces...
FIGURES
First thumbnail for: 10 Be analysis of amalgamated talus pebbles to inv...
Second thumbnail for: 10 Be analysis of amalgamated talus pebbles to inv...
Third thumbnail for: 10 Be analysis of amalgamated talus pebbles to inv...
View PDF for article title, 10 Be analysis of amalgamated talus pebbles to investigate alpine erosion, Garnet Canyon, <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>, Wyoming
Add to Citation Manager for 10 Be analysis of amalgamated talus pebbles to investigate alpine erosion, Garnet Canyon, <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>, Wyoming
Journal Article

Geochronology of Precambrian Rocks of the Teton Range, Wyoming Available to Purchase

JOHN C. REED, JR., R. E. ZARTMAN
Journal: GSA Bulletin
Published: 01 February 1973
GSA Bulletin (1973) 84 (2): 561–582.
DOI: https://doi.org/10.1130/0016-7606(1973)84<561:GOPROT>2.0.CO;2
...JOHN C. REED, JR.; R. E. ZARTMAN Abstract Note: This paper is dedicated to Aaron and Elizabeth Waters on the occasion of Dr. Waters' retirement. The oldest rocks in the Teton Range are complexly deformed interlayered biotite gneiss, plagioclase gneiss, amphibole gneiss, and amphibolite. Also...
View PDF for article title, Geochronology of Precambrian Rocks of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>, Wyoming
Purchase
Add to Citation Manager for Geochronology of Precambrian Rocks of the <span class="search-highlight">Teton</span> <span class="search-highlight">Range</span>, Wyoming
Book Chapter

Fracture patterns associated with the evolution of the Teton anticline, Sawtooth Range, Montana, USA Available to Purchase

Author(s)
C. M. Burberry, D. L. Cannon, J. W. Cosgrove, T. Engelder
Book: Folding and Fracturing of Rocks: 50 Years of Research since the Seminal Text Book of J. G. Ramsay
Series: Geological Society, London, Special Publications
Publisher: Geological Society of London
Published: 02 January 2020
DOI: 10.1144/SP487.12
EISBN: 9781786204721
... Abstract The Teton anticline and adjacent structures, in the Sawtooth Range, Montana, USA, are fractured in such a way that may be taken as a model for fractures propagating during buckle folding. However, advances in understanding both the process of folding in forelands and the evolution...
Abstract
View PDF for content titled, Fracture patterns associated with the evolution of the <span class="search-highlight">Teton</span> anticline, Sawtooth <span class="search-highlight">Range</span>, Montana, USA
Purchase
Add to Citation Manager for Fracture patterns associated with the evolution of the <span class="search-highlight">Teton</span> anticline, Sawtooth <span class="search-highlight">Range</span>, Montana, USA

Abstract The Teton anticline and adjacent structures, in the Sawtooth Range, Montana, USA, are fractured in such a way that may be taken as a model for fractures propagating during buckle folding. However, advances in understanding both the process of folding in forelands and the evolution of fracture patterns found within these folds suggest that it is time to reinterpret the nexus between fracturing and folding within these classic structures. With the benefit of seismic lines, the Teton anticline is best described as a fault-propagation fold. Joint propagation initiated with the formation of two major sets whose orientation is controlled by pre-folding, regional stresses. Two more joint sets propagated in local stress fields, developed in response to anticline growth. Some early joints were reactivated as wrench faults during amplification and tightening of the anticlines. The fracture sets identified are consistent with: (a) propagation in a regional stress field, which may be related to stretching in the Sawtooth Range orocline; and (b) tangential longitudinal strain of the backlimb and forcing or trishear of the forelimb during anticline development. Thus, we suggest that fracture networks across folded structures should be interpreted and characterized in the light of the geological history of the entire system.

Journal Article

Structural controls of fracture orientations, intensity, and connectivity, Teton anticline, Sawtooth Range, Montana Available to Purchase

Kajari Ghosh, Shankar Mitra
Journal: AAPG Bulletin
Published: 01 August 2009
AAPG Bulletin (2009) 93 (8): 995–1014.
DOI: https://doi.org/10.1306/04020908115
...Kajari Ghosh; Shankar Mitra Abstract The Teton anticline is a multiple hinge anticline containing fractured Mississippian–Devonian carbonates in the frontal part of the Sawtooth Range in Montana. The structure serves as a good surface analog for fracture patterns and connectivities within...
FIGURES
First thumbnail for: Structural controls of fracture orientations, inte...
Second thumbnail for: Structural controls of fracture orientations, inte...
Third thumbnail for: Structural controls of fracture orientations, inte...
View PDF for article title, Structural controls of fracture orientations, intensity, and connectivity, <span class="search-highlight">Teton</span> anticline, Sawtooth <span class="search-highlight">Range</span>, Montana
Purchase
Add to Citation Manager for Structural controls of fracture orientations, intensity, and connectivity, <span class="search-highlight">Teton</span> anticline, Sawtooth <span class="search-highlight">Range</span>, Montana
Image
Surface trace of the Teton normal fault (TF) at the base of the Teton Range and other Quaternary faults in Jackson Hole from Zellman et al. (2019) shown as bold lines with ball and bar on the downthrown side. Paleoseismic sites shown as squares and labeled with site name; year of trench excavation is included in parentheses. Possible paleoseismic features from Pierce et al. (1998) in northern Jackson Lake are labeled “L” (liquefaction) and “D” (backflooded delta). Extents of Grand Teton National Park (GRTE) and John D. Rockefeller Memorial Parkway (JDRMP) are shown. BL, Bradley Lake; CO, Colorado; ID, Idaho; JL, Jenny Lake; LC, Leigh Canyon; LL, Leigh Lake; MB, Moran Bay; MT, Montana; NV, Nevada; PC, Paintbrush Canyon; PL, Phelps Lake; PVF, Phillips Valley fault; TL, Taggart Lake; UT, Utah; WY, Wyoming. See Data and Resources for base map data sources. The inset figure shows the location within northwest Wyoming. The color version of this figure is available only in the electronic edition.

Surface trace of the Teton normal fault (TF) at the base of the Teton Range... Available to Purchase

Published: 19 November 2019
Figure 1. Surface trace of the Teton normal fault (TF) at the base of the Teton Range and other Quaternary faults in Jackson Hole from Zellman et al. (2019) shown as bold lines with ball and bar on the downthrown side. Paleoseismic sites shown as squares and labeled with site name; year
Image
Figure 1. Location map of Teton Range and surface trace of Teton fault (black solid line with bars on downthrown side). Note drainage divide (solid gray line) located west of range crest (dashed line). Light-gray line marks southern rim of Yellowstone ice cap (Love et al., 2003). Black and white triangles mark peaks of Grand Teton (4197 m) and Mt. Moran (3842 m), respectively.

Figure 1. Location map of Teton Range and surface trace of Teton fault (bla... Available to Purchase

Published: 01 December 2007
Figure 1. Location map of Teton Range and surface trace of Teton fault (black solid line with bars on downthrown side). Note drainage divide (solid gray line) located west of range crest (dashed line). Light-gray line marks southern rim of Yellowstone ice cap ( Love et al., 2003 ). Black and white
Image
εNd vs. age diagram for rocks from the Teton Range, the Wind River Range, and western Owl Creek Mountains. LG, layered gneiss.

ε Nd vs. age diagram for rocks from the Teton Range, the Wind River Range,... Available to Purchase

Published: 06 January 2007
Fig. 11. ε Nd vs. age diagram for rocks from the Teton Range, the Wind River Range, and western Owl Creek Mountains. LG, layered gneiss.
Image
Location map of the Teton Range (Wyoming, USA) with the simplified surface trace of the Teton fault (black solid line with bars on downthrown side). Black and white triangles mark the peaks of Grand Teton (4197 m) and Mount Moran (3842 m), respectively. Transparent white area with gray outline marks the southern extent of the Last Glacial Maximum (LGM) Yellowstone ice cap, which reached a thickness of ~1 km farther north on the Yellowstone Plateau, and of the LGM Teton Range valley glaciers, which reached ice thicknesses of several hundred meters (Love, 2003; Licciardi and Pierce, 2018). Note that Jenny Lake is located at the southern margin of the former Yellowstone ice cap (Licciardi and Pierce, 2018). ID—Idaho; MT—Montana; WY—Wyoming.

Location map of the Teton Range (Wyoming, USA) with the simplified surface ... Open Access

Published: 21 July 2021
Figure 1. Location map of the Teton Range (Wyoming, USA) with the simplified surface trace of the Teton fault (black solid line with bars on downthrown side). Black and white triangles mark the peaks of Grand Teton (4197 m) and Mount Moran (3842 m), respectively. Transparent white area with gray
Image
Location of the scanline within the Teton Range, NW Wyoming. (a) Geology, highlighting the Late Archean Mount Owen Quartz Monzonite (Wg) and the location of the scanline (inset b). Modified after Love et al. (1992) and Zartman &amp; Reed (1998). TF, Teton Fault; BMF, Buck Mountain reverse fault; FPRF, Forellen Peak reverse fault. The elevation of the outcrop is 2589 m, about 80 m vertically below the basal Cambrian unconformity. (b) Upper Teton Canyon, GoogleEarth image, showing the large exposure (around the red diamond labelled ‘Scanline’) north of the Teton Canyon trail (dash-dot line) (location: a and inset b). Our example of clustering is in a readily accessible exposure. (c) View of the outcrop looking SE; the prominent peak in the centre of the image is Buck Mountain. P, polished surface of the granodiorite; W, outcrop with the polished surface weathered away. The field of view of the pavement is c. 40 m.

Location of the scanline within the Teton Range, NW Wyoming. ( a ) Geology,... Open Access

Published: 01 July 2019
Fig. 1. Location of the scanline within the Teton Range, NW Wyoming. ( a ) Geology, highlighting the Late Archean Mount Owen Quartz Monzonite (Wg) and the location of the scanline (inset b). Modified after Love et al. (1992) and Zartman & Reed (1998) . TF, Teton Fault; BMF, Buck Mountain
Image
Structural data for the northern Teton Range. (A) Poles to the F2 foliations in the Moose Basin area. (B) Lineations (mostly L2 lineations) in the Moose Basin area. (C) Poles to foliations across the whole northern Teton Range. Cylindrical fit to the foliations defines the F3 fold, which has a trend of 20° and a plunge of 24°. (D) Lineations (mostly L2) from across the northern Teton Range. The lineations have a strong maximum near the axial trend of the F3 fold axes. Diagrams were calculated from program Stereonet (Cardozo and Allmendinger, 2013). Contour intervals are 2σ above standard deviation (Kamb, 1959).

Structural data for the northern Teton Range. (A) Poles to the F 2 foliati... Open Access

Published: 07 May 2018
Figure 5. Structural data for the northern Teton Range. (A) Poles to the F 2 foliations in the Moose Basin area. (B) Lineations (mostly L 2 lineations) in the Moose Basin area. (C) Poles to foliations across the whole northern Teton Range. Cylindrical fit to the foliations defines the F 3 fold
Image
Geologic map across the northern Teton Range showing the relations between the high-pressure granulites (Moose Basin gneiss), leucogranites (undifferentiated Webb Canyon and Bitch Creek gneisses of Frost et al., 2016) and Layered Gneiss. Modified after Love et al. (1992). Numbers identify the samples cited in this paper. Two samples of Moose Basin gneiss analyzed for Sm-Nd isotopic compositions are located south of the map area (08T10 and 08T25).

Geologic map across the northern Teton Range showing the relations between ... Open Access

Published: 07 May 2018
Figure 2. Geologic map across the northern Teton Range showing the relations between the high-pressure granulites (Moose Basin gneiss), leucogranites (undifferentiated Webb Canyon and Bitch Creek gneisses of Frost et al., 2016 ) and Layered Gneiss. Modified after Love et al. (1992) . Numbers
Image
P-T-t path inferred for the northern Teton Range.

P-T-t path inferred for the northern Teton Range. Open Access

Published: 07 May 2018
Figure 12. P-T-t path inferred for the northern Teton Range.
Image
Summary of geochronology of the northern Teton Range. The age of high-pressure metamorphism (M1) is interpreted from U-Pb zircon ages in the leucosome of partially melted mafic granulite (sample 06T16). The timing of tectonic assembly and M2 amphibolite grade metamorphism is provided by the age of leucosome in partially melted Layered Gneiss (06T9). Leucogranitic gneisses were intruded coincident with tectonic assembly; samples of two distinct leucogranitic suites, the Bitch Creek gneiss and the Webb Canyon Gneiss, are described in detail by Frost et al. (2016) and are arranged in order of their location from east to west.

Summary of geochronology of the northern Teton Range. The age of high-press... Open Access

Published: 07 May 2018
Figure 13. Summary of geochronology of the northern Teton Range. The age of high-pressure metamorphism (M1) is interpreted from U-Pb zircon ages in the leucosome of partially melted mafic granulite (sample 06T16). The timing of tectonic assembly and M2 amphibolite grade metamorphism is provided
Image
Selected trace-element abundances for Archean rocks of the Teton Range. (A) Rb content as a function of SiO2. (B) Sr content as a function of SiO2. MBG—Moose Basin gneiss; NLG—Northern Layered Gneiss; TTG—tonalite-trondhjemite-granodiorite.Symbols are the same as in Figure 7.

Selected trace-element abundances for Archean rocks of the Teton Range. (A)... Open Access

Published: 11 April 2018
Figure 9. Selected trace-element abundances for Archean rocks of the Teton Range. (A) Rb content as a function of SiO 2 . (B) Sr content as a function of SiO 2 . MBG—Moose Basin gneiss; NLG—Northern Layered Gneiss; TTG—tonalite-trondhjemite-granodiorite.Symbols are the same as in Figure 7 .
Image
Pressure-temperature-time path for gneisses from the Teton Range. M1 and M2 are recorded only in the northern Tetons. The M1 high-pressure granulite event was dated at 2695 Ma and determined by garnet-rutile-aluminosilicate-ilmenite-quartz (GRAIL) barometry and Zr-in-rutile thermometry to have occurred at &gt;12 kbar and a minimum of 900 °C. The M2 event is marked by partial melting of Layered Gneiss in the presence of staurolite at 2685 Ma. M3 is recorded in garnet amphibolites from the northern portion of the range. It is interpreted as an amphibolite-facies metamorphic event accompanying accretion of the northern and southern domains of the Teton Range along the Moran deformation zone at ca. 2.62 Ga. Ky—kyanite, Sil—sillimanite, And—andesite.

Pressure-temperature-time path for gneisses from the Teton Range. M 1 and ... Open Access

Published: 11 April 2018
Figure 18. Pressure-temperature-time path for gneisses from the Teton Range. M 1 and M 2 are recorded only in the northern Tetons. The M 1 high-pressure granulite event was dated at 2695 Ma and determined by garnet-rutile-aluminosilicate-ilmenite-quartz (GRAIL) barometry and Zr-in-rutile