1-20 OF 856 RESULTS FOR

Turtle Mountain

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

Terrestrial palynomorph biostratigraphy of the Cypress Hills, Wood Mountain, and Turtle Mountain areas (Upper Cretaceous - Paleocene) of western Canada Free

D R Braman, A R Sweet
Published: 01 October 1999
Canadian Journal of Earth Sciences (1999) 36 (5): 725–741.
DOI: https://doi.org/10.1139/e98-003
...; and a third on the western edge of Turtle Mountain near Goodlands, Manitoba. The terrestrial elements of the palynological assemblages are discussed. The Maastrichtian assemblages encompassed the Scollardia trapaformis Zone and two new subzones, Myrtipites scabratus - Aquilapollenites delicatus var. collaris...
Add to Citation Manager for Terrestrial palynomorph biostratigraphy of the Cypress Hills, Wood <span class="search-highlight">Mountain</span>, and <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span> areas (Upper Cretaceous - Paleocene) of western Canada
Journal Article

A reconstruction of the early Palaeocene palaeovegetation of Turtle Mountain, south-western Manitoba, Canada Available to Purchase

Nidhi U. Patel, David R. Greenwood, Cathy L. Greenwood, Jennifer M. Galloway, Mackenzie Desautels
Journal: Palynology
Published: 02 October 2022
Palynology (2022) 46 (4): 1–16.
DOI: https://doi.org/10.1080/01916122.2022.2064555
...Nidhi U. Patel; David R. Greenwood; Cathy L. Greenwood; Jennifer M. Galloway; Mackenzie Desautels Abstract The lower Goodlands Member of the Turtle Mountain Formation is exposed in a streambank outcrop on the western flank of Turtle Mountain, south-western Manitoba, Canada (49°0′2″N, 100°14′51″W...
FIGURES | View All (8)
View PDF for article title, A reconstruction of the early Palaeocene palaeovegetation of <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span>, south-western Manitoba, Canada
Purchase
Add to Citation Manager for A reconstruction of the early Palaeocene palaeovegetation of <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span>, south-western Manitoba, Canada
Book Chapter

Structural analysis of Turtle Mountain: origin and influence of fractures in the development of rock slope failures Available to Purchase

Author(s)
Andrea Pedrazzini, Michel Jaboyedoff, Corey R. Froese, C. Willem Langenberg, Francisco Moreno
Book: Slope Tectonics
Series: Geological Society, London, Special Publications
Publisher: The Geological Society of London
Published: 01 January 2011
DOI: 10.1144/SP351.9
EISBN: 9781862395992
... fractures on slope instabilities with emphasis on Turtle Mountain, located in SW Alberta (Canada). The structural features of Turtle Mountain, especially to the south of the 1903 Frank Slide, were investigated using a high-resolution digital elevation model combined with a detailed field survey...
FIGURES | View All (15)
Abstract
View PDF for content titled, Structural analysis of <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span>: origin and influence of fractures in the development of rock slope failures
Purchase
Add to Citation Manager for Structural analysis of <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span>: origin and influence of fractures in the development of rock slope failures

Abstract Large slope failures in fractured rocks are often controlled by the combination of pre-existing tectonic fracturing and brittle failure propagation in the intact rock mass during the pre-failure phase. This study focuses on the influence of fold-related fractures and of post-folding fractures on slope instabilities with emphasis on Turtle Mountain, located in SW Alberta (Canada). The structural features of Turtle Mountain, especially to the south of the 1903 Frank Slide, were investigated using a high-resolution digital elevation model combined with a detailed field survey. These investigations allowed the identification of six main discontinuity sets influencing the slope instability and surface morphology. According to the different deformation phases affecting the area, the potential origin of the detected fractures was assessed. Three discontinuity sets are correlated with the folding phase and the others with post-folding movements. In order to characterize the rock mass quality in the different portions of the Turtle Mountain anticline, the geological strength index (GSI) has been estimated. The GSI results show a decrease in rock mass quality approaching the fold hinge area due to higher fracture persistence and higher weathering. These observations allow us to propose a model for the potential failure mechanisms related to fold structures.

Journal Article

Seismic imaging of the Turtle Mountain structure, southwestern Alberta, Canada Available to Purchase

J.H. Isaac, D.C. Lawton, C.W. Langenberg
Published: 01 September 2008
Bulletin of Canadian Petroleum Geology (2008) 56 (3): 199–208.
DOI: https://doi.org/10.2113/gscpgbull.56.3.199
...J.H. Isaac; D.C. Lawton; C.W. Langenberg Abstract We reprocessed in time and depth two seismic lines from the Turtle Mountain area of Southern Alberta, Canada. Our objective was to improve the seismic imaging of the complex structures that form the mountain. Processing in the time domain...
FIGURES | View All (9)
View PDF for article title, Seismic imaging of the <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span> structure, southwestern Alberta, Canada
Purchase
Add to Citation Manager for Seismic imaging of the <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span> structure, southwestern Alberta, Canada
Journal Article

Mapping fractures with GPR: A case study from Turtle Mountain Available to Purchase

Ulrich Theune, Dean Rokosh, Mauricio D. Sacchi, Douglas R. Schmitt
Journal: Geophysics
Published: 30 August 2006
Geophysics (2006) 71 (5): B139–B150.
DOI: https://doi.org/10.1190/1.2335515
...Ulrich Theune; Dean Rokosh; Mauricio D. Sacchi; Douglas R. Schmitt Abstract Ground-penetrating radar (GPR) surveys were acquired of rocks on the highly fractured summit of Turtle Mountain in Canada. In 1903 a disastrous rock slide occurred at Turtle Mountain and it still poses a geologic hazard...
FIGURES | View All (13)
View PDF for article title, Mapping fractures with GPR: A case study from <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span>
Purchase
Add to Citation Manager for Mapping fractures with GPR: A case study from <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span>
Journal Article

Campanian to Paleocene dinoflagellate assemblages from the Turtle Mountain core hole, Manitoba, western Canada Free

David J McIntyre
Published: 01 October 1999
Canadian Journal of Earth Sciences (1999) 36 (5): 769–774.
DOI: https://doi.org/10.1139/e98-011
...David J McIntyre Abstract Dinoflagellate assemblages from the Turtle Mountain core hole provide evidence for the Paleocene age of the Turtle Mountain Formation and confirm that the Boissevain Formation and the Coulter Member of the Pierre Formation are Maastrichtian. Evidence from dinoflagellates...
Add to Citation Manager for Campanian to Paleocene dinoflagellate assemblages from the <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span> core hole, Manitoba, western Canada
Journal Article

Paleocene dinoflagellates from the Turtle Mountain Formation, southwestern Manitoba, Canada Free

Hiroshi Kurita, David J. McIntyre
Journal: Palynology
Published: 01 October 1995
Palynology (1995) 19 (1): 119–136.
...Hiroshi Kurita; David J. McIntyre Abstract Shallow marine deposits of the Paleocene Turtle Mountain Formation on the northeastern flank of the Williston Basin, southwestern Manitoba, yielded dinoflagellate assemblages which include Senegalinium microgranulatum, S. obscurum, Senegalinium sp...
Add to Citation Manager for Paleocene dinoflagellates from the <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountain</span> Formation, southwestern Manitoba, Canada
Journal Article

The manganese deposits of the Turtle Mountains, North Dakota Available to Purchase

Thomas Andrews Hendricks, Wilson Morrow Laird
Journal: Economic Geology
Published: 01 November 1943
Economic Geology (1943) 38 (7): 591–602.
DOI: https://doi.org/10.2113/gsecongeo.38.7.591
...Thomas Andrews Hendricks; Wilson Morrow Laird Abstract The principal manganese spring deposits in the Turtle Mountains of North Dakota were investigated and mapped in detail. One of these, Mineral Spring, located in the N 1/2 NE 1/4 Section 22, T. 162 N., R. 73 W., was found to contain...
View PDF for article title, The manganese deposits of the <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountains</span>, North Dakota
Purchase
Add to Citation Manager for The manganese deposits of the <span class="search-highlight">Turtle</span> <span class="search-highlight">Mountains</span>, North Dakota
Image
Map indicating the location of Turtle Mountain, Manitoba, major rock formations, the location of abandoned coal mines and prior palynology sampling (Canadian Continental Drilling Program core/CCDP), and the sample sites WP-6, WP-7, WP-8 and WP-9. Base map redrawn and modified from Banatyne (1979, fig. 1). The inset map of North America shows the location of the Chicxulub crater (red double circle) and also the approximate position and extent of the Western Interior Seaway at 65.5 Ma (light blue shading).

Map indicating the location of Turtle Mountain, Manitoba, major rock format... Available to Purchase

Published: 02 October 2022
Figure 1. Map indicating the location of Turtle Mountain, Manitoba, major rock formations, the location of abandoned coal mines and prior palynology sampling (Canadian Continental Drilling Program core/CCDP), and the sample sites WP-6, WP-7, WP-8 and WP-9. Base map redrawn and modified from
Image
Stratigraphical correlation chart of the Lower Palaeocene Turtle Mountain Formation and other major rock formations of southern Alberta and Saskatchewan, that include K–Pg rocks studied palynologically. Based in part on Braman (2018) and Lerbekmo (1999).

Stratigraphical correlation chart of the Lower Palaeocene Turtle Mountain F... Available to Purchase

Published: 02 October 2022
Figure 2. Stratigraphical correlation chart of the Lower Palaeocene Turtle Mountain Formation and other major rock formations of southern Alberta and Saskatchewan, that include K–Pg rocks studied palynologically. Based in part on Braman ( 2018 ) and Lerbekmo ( 1999 ).
Image
Lithological column for Site WP-9 of the Goodlands Member, Turtle Mountain Formation, showing the lithological units U1–U3, and the location of the seven palynological samples within the 150 cm measured section.

Lithological column for Site WP-9 of the Goodlands Member, Turtle Mountain ... Available to Purchase

Published: 02 October 2022
Figure 4. Lithological column for Site WP-9 of the Goodlands Member, Turtle Mountain Formation, showing the lithological units U1–U3, and the location of the seven palynological samples within the 150 cm measured section.
Image
Important Turtle Mountain Formation pteridophyte spore and gymnosperm pollen taxa. Given are the sample number, Geological Survey of Canada (GSC) curation number (C-number), GSC Calgary Palynology Laboratory preparation number (P-number), and England Finder coordinates. Scale bar = 20 mm. 1. Stereigranisporis regius (Drozhastichich) Ravn &amp; Witzke 1995, sample 5, C-477581, P5065-5B, R42/2. 2. Stereisporites antiquasporites (Wilson &amp; Webster) Dettmann 1963, sample 5, C-477581, P5065-5B, E20/3. 3. Stereisporites ancoris Krutzsch 1963, sample 5, C-477581, P5065-5B, O35/3. 4. Stereisporites electus (Mamczar) Krutzsch 1963, sample 7, C-477583, P5065-7A, J19/4. 5. Reticuloidosporites pseudomurii Elsik 1968, sample 7, C-477583, P5065-7A, W33/1. 6. Cingulatisporites dakotaensis Stanley 1965, sample 5, C-477581, P5065-5B, M9/4. 7. Cingutriletes clavus (Balme) Dettmann 1963, sample 5, C-477581, P5065-5B, J40. 8. Schizea sp., sample 6, C-477582, P5065-6A, Q42/1. 9. Laevigatosporites haardti (Potonié &amp; Venitz) Thomson &amp; Pflug 1953, sample 3, C-477579, P5065-3A, V17/2. 10. Cyathidites minor Couper 1953, sample 5, C-477581, P5065-5B, H34/1. 11. Gleicheniidites delicatus (Bolkhovitina) Krutzsch 1959, sample 2, C-477578, P5065-2A, L34/3. 12. Foveosporites subtriangularis (Brenner) Doring 1966, sample 5, C-477581, P5065-5B, B49/3. 13. Gleicheniidites senonicus Ross 1949, sample 5, C-477581, P5065-5B, L40/1. 14. Seductisporites barbatus Tschudy 1973, sample 5, C-477581, P5065-5B, G41/0. 15. Hazaria sheopiarii Srivastava 1971, sample 2, C-477578, P5065-2A, E44/0. 16. Cibotiumspora jurienensis (Balme) Filatoff 1975, sample 1, C-477577, P5065-1B, D28/4. 17. Baculatisporites comaumensis (Cookson) Potonié 1956, sample 6, C-4477582, P5065-6A, Q33/4. 18. Cupressacites hiatipites (Wodehouse 1933) Krutzsch 1971, sample 5, C-477581, P5065-5B, G43/0. 19. Cycadopites sp., sample 3, C-477589, P5065-3A, U10/0. 20. Pinuspollenites sp. Erdtman 1943, sample 5, C-477581, P5065-5B, O40/0. 21. Sequoiapollenites paleonicus Stanley 1965, sample 2, C-477578, P5065-2A, P31/1. 22. Cupressacites hiatipites (Wodehouse 1933) Krutzsch 1971, sample 5, C-477581, P5065-5B, G43/0. 23. Cycadopites sp., sample 5, C-477581, P5065-5B, K22/1.

Important Turtle Mountain Formation pteridophyte spore and gymnosperm polle... Available to Purchase

Published: 02 October 2022
Plate 1. Important Turtle Mountain Formation pteridophyte spore and gymnosperm pollen taxa. Given are the sample number, Geological Survey of Canada (GSC) curation number (C-number), GSC Calgary Palynology Laboratory preparation number (P-number), and England Finder coordinates. Scale bar = 20 mm
Image
Important Turtle Mountain Formation angiosperm pollen taxa. Given are the sample number, Geological Survey of Canada (GSC) curation number (C-number), GSC Calgary Palynology Laboratory preparation number (P-number), and England Finder coordinates. Scale bar = 10 mm. 1. Alnipollenites trina (Stanley) Norton in Norton &amp; Hall 1969, sample 3, C-477579, P5065-3A, O10/4. 2. Alnipollenites quadrapollenites (Rouse) Srivastava 1966 sample 5, C-477581, P5065-5B, N28/2. 3. Alnipollenites verus Potonié (Potonié) 1934, sample 5, C-477581, P5065-5B, P38/2. 4. Ulmoideipites hebridicus (Simpson) Sweet 1986, sample 3, C-477579, P5065-3A, L28/2. 5. Cupuliferoipollenites sp. sample 5, C-477581, P5065-5B, F30/4. 6. Ulmipollenites tricostatus (Anderson) Farabee &amp; Canright 1986, sample 2, C-477578, P5065-2A, S22/1. 7. Ulmipollenites krempii (Anderson) Frederiksen 1979, sample 3, C-477579, P5065-3A, W33/0. 8. Tricolpites hians Stanley 1965, sample 6, C-477582, P5065-6A, M30/0. 9. Dyadonapites reticulatus Tschudy 1973, sample 1, C-477577, P5065-1B, G41/0. 10. Tricolporites sp., sample 7, C-477583, P5065-7A, P34/1. 11. Cranwellia sp., sample 3, C-477579, P5065-3A, Q38/4. 12. Kurtzipites trispissatus Anderson 1960, sample 3, C-477579, P5065-3A, T41/1. 13. Tricolpites anguloluminosus Anderson 1960, sample 7, C-477583, P5065-7A, U13/4. 14. Erdtmanipollis procumbentiformis (Samoilovitch) Krutzsch 1966, sample 2, C-477578, P5065-2A, T21/1. 15. Arecipites sp., sample 3, C-477579, P5065-3A, G10/4. 16. Liliacidites complexus (Stanley) Leffingwell 1971, sample 2, C-477578, P-5065-2A, S32/4. 17. Triporopollenites plektosus Anderson 1960, sample 7, C-, P5065-7A, J61/0. 18. Fraxinoipollenites variabilis Stanley 1965, sample 7, C-477577, P5065-7A, H21/4. 19. Simplicepollis rallus (Stanley) Nichols &amp; Brown 1992, sample 5, C-477581, P5065-5B, R26/1. 20. Tricolporopollenites kruschii (Potonié) Thomson &amp; Pflug 1953, sample 7, C-477583, P5065-7A, H20/0. 21. Tricolpites sp., sample 3, C-477579, P5065-3A, M21/2. 22. Myrtaceidites solidus Sweet 1986, sample 5, C-477581, P5065-5B, E33/3. 23. Momipites wyomingensis Nichols &amp; Ott 1978, sample 3, C-477579, P5065-3A, J28/4. 24. Syncolporites minimus Leffingwell 1971, sample 3, C-477579, P5065-3A, R37/2. 25. Momipites amplus (Leffingwell) Nichols 1973, sample 3, C-477579, P5065-3A, Q37/1. 26. Momipites tenuipolus Anderson 1960, sample 1, C-477577, P5065-1B, V27/1. 27. Pandaniidites typicus (Norton) Sweet 1986, sample 5, C-477581, P5065-5B, S20. 28. Tilia crassipites Wodehouse 1933, sample 5, C-477581, P5065-5B, S34/2.

Important Turtle Mountain Formation angiosperm pollen taxa. Given are the s... Available to Purchase

Published: 02 October 2022
Plate 2. Important Turtle Mountain Formation angiosperm pollen taxa. Given are the sample number, Geological Survey of Canada (GSC) curation number (C-number), GSC Calgary Palynology Laboratory preparation number (P-number), and England Finder coordinates. Scale bar = 10 mm. 1. Alnipollenites
Image
Views of Turtle Mountain after the rock avalanche. (a) The slide as seen from the east. (b) A view of the slide deposit area as seen from the top of the mountain looking eastward. The study area is at the summit, on the back side of Figure 2a.

Views of Turtle Mountain after the rock avalanche. (a) The slide as seen fr... Available to Purchase

Published: 30 August 2006
Figure 2. Views of Turtle Mountain after the rock avalanche. (a) The slide as seen from the east. (b) A view of the slide deposit area as seen from the top of the mountain looking eastward. The study area is at the summit, on the back side of Figure 2a .
Image
(a) Geologic map of the Turtle Mountain area. Contour lines show elevation in meters. The approximate section covered by Figure 4 is indicated by the dashed rectangle around South Peak. (b) Schematic cross section follows the profile AA′. F1 and F2 indicate two orientations of deep fractures within the mountain. (After Cruden and Krahn, 1973.)

(a) Geologic map of the Turtle Mountain area. Contour lines show elevation ... Available to Purchase

Published: 30 August 2006
Figure 3. (a) Geologic map of the Turtle Mountain area. Contour lines show elevation in meters. The approximate section covered by Figure 4 is indicated by the dashed rectangle around South Peak. (b) Schematic cross section follows the profile AA ′ . F1 and F2 indicate two
Image
Aerial photograph of summit, Turtle Mountain. The line labeled B′B shows the location of one of three profiles; lines C′C and PP′ show locations of the remaining two profiles. Lengths of profiles are approximate. Orientations of sets of fractures are shown by stereonet diagrams. Three diagrams show orientations of fractures at sites indicated by thick black lines. One diagram shows orientations of open cracks in the borehole, and one shows orientations of large open cracks at the summit of Turtle Mountain. Dashed line AA′ indicates the approximate position of schematic cross section AA′ in Figure 3b. Horizontal scale is approximate. (Photograph and stereonet diagrams courtesy of the Government of Alberta.)

Aerial photograph of summit, Turtle Mountain. The line labeled B ′ ... Available to Purchase

Published: 30 August 2006
Figure 4. Aerial photograph of summit, Turtle Mountain. The line labeled B ′ B shows the location of one of three profiles; lines C ′ C and PP ′ show locations of the remaining two profiles. Lengths of profiles are approximate. Orientations of sets of fractures
Image
GPR data acquired at the west slope of Turtle Mountain (Figure 4); data were modified by basic processing. (a): Processed 100-MHz data. Filled and open triangles indicate locations of fractures at the surface, along the profile. Black triangles indicate fractures visible at the surface, on the line of profile; white triangles indicate fractures at the surface, but to the left or right of the line of profile. (b) Processed 50-MHz data. In both profiles, bedding planes are shown as coherent events that dip from left to right.

GPR data acquired at the west slope of Turtle Mountain (Figure 4 ); data w... Available to Purchase

Published: 30 August 2006
Figure 7. GPR data acquired at the west slope of Turtle Mountain (Figure 4 ); data were modified by basic processing. (a): Processed 100-MHz data. Filled and open triangles indicate locations of fractures at the surface, along the profile. Black triangles indicate fractures visible
Journal Article

Upper Cretaceous - lower Tertiary lithostratigraphic relationships of three cores from Alberta, Saskatchewan, and Manitoba, Canada Free

D R Braman, A R Sweet, J F Lerbekmo
Published: 01 October 1999
Canadian Journal of Earth Sciences (1999) 36 (5): 669–683.
DOI: https://doi.org/10.1139/e97-108
... been encountered subdividing the interval between the Bearpaw and Ravenscrag formations into separate formations and provides a cored record of all the Ravenscrag coals within the Wood Mountain area. The core hole drilled at Turtle Mountain, Manitoba, recovered core from the Turtle Mountain Formation...
Add to Citation Manager for Upper Cretaceous - lower Tertiary lithostratigraphic relationships of three cores from Alberta, Saskatchewan, and Manitoba, Canada
Journal Article

Magnetostratigraphy of the Canadian Continental Drilling Program Cretaceous-Tertiary (K-T) Boundary Project core holes, western Canada Free

J F Lerbekmo
Published: 01 October 1999
Canadian Journal of Earth Sciences (1999) 36 (5): 705–715.
DOI: https://doi.org/10.1139/e98-066
... (49°05'N, 106°16'W) spans the interval from magnetozone 28n to 30r in the Ravenscrag, Frenchman, Battle, Whitemud, Eastend, and Bearpaw formations. The Cretaceous-Tertiary boundary is present in 29r. The Turtle Mountain core (49°01'N, 100°33'W) has a number of significant disconformities; only...
Add to Citation Manager for Magnetostratigraphy of the Canadian Continental Drilling Program Cretaceous-Tertiary (K-T) Boundary Project core holes, western Canada
Journal Article

Structural geology of the modern Frank Slide and ancient Bluff Mountain Slide, Crowsnest, Alberta Available to Purchase

Peter B. Jones
Published: 01 June 1993
Bulletin of Canadian Petroleum Geology (1993) 41 (2): 232–243.
DOI: https://doi.org/10.35767/gscpgbull.41.2.232
...Peter B. Jones ABSTRACT The Frank Slide of 1903 occurred in Mississippian carbonates in the east flank of the Turtle Mountain anticline in the southern Alberta foothills. This paper presents the hypothesis that eastward-directed folded thrust faults may have been a factor contributing...
View PDF for article title, Structural geology of the modern Frank Slide and ancient Bluff <span class="search-highlight">Mountain</span> Slide, Crowsnest, Alberta
Purchase
Add to Citation Manager for Structural geology of the modern Frank Slide and ancient Bluff <span class="search-highlight">Mountain</span> Slide, Crowsnest, Alberta