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Journal Article

Cross-strike potential-field anomalies in the Canadian Cordillera Available to Purchase

Frederick A. Cook, C. Elissa Lynn, Kevin W. Hall
Published: 10 January 2002
Canadian Journal of Earth Sciences (2003) 40 (1): 1–11.
DOI: https://doi.org/10.1139/e02-100
... of these, the SteamboatFraser trend, is a north–south-striking feature that projects from the foreland belt in northeastern British Columbia, where it becomes subparallel to anomalies east of the Mackenzie Mountains, southward to the northern limit of the Fraser River strike-slip fault, a distance of about 600 km...
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View PDF for article title, Cross-strike potential-field anomalies in the Canadian Cordillera
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Image
Magnetic anomaly map of the same region as shown in Fig. 1 (Geological Survey of Canada 1999b). GBma, Great Bear magmatic arc; SF, Steamboat–Fraser trend. Other abbreviations as in Figs. 1 and 2.

Magnetic anomaly map of the same region as shown in Fig.  1 ( Geological S... Available to Purchase

Published: 23 September 2005
Fig. 3. Magnetic anomaly map of the same region as shown in Fig.  1 ( Geological Survey of Canada 1999 b ). GBma, Great Bear magmatic arc; SF, SteamboatFraser trend. Other abbreviations as in Figs.  1 and 2 .
Image
Schematic interpretation illustrating the possible linear zone of high-density rock along the Steamboat–Fraser trend. The linearity of the trend is suggested to be a deep-seated feature, such as a dike or fault (dotted pattern) whose age is unknown. High-density and high magnetic susceptibility rocks in the upper crust are shown as dikes and volcanics that migrated upward and were extruded in a few areas, but remained at depth elsewhere. In the south, the shallow magnetic rocks are located east of the gravity trend (Fig. 5c). A possible interpretation of this is that mafic rocks intruded at a shallow level laterally offset from a deep source. CDF, Cordilleran deformation front; TT–NRMT, Tintina Trench – northern Rocky Mountain Trench.

Schematic interpretation illustrating the possible linear zone of high-dens... Available to Purchase

Published: 10 January 2002
Fig. 9. Schematic interpretation illustrating the possible linear zone of high-density rock along the SteamboatFraser trend. The linearity of the trend is suggested to be a deep-seated feature, such as a dike or fault (dotted pattern) whose age is unknown. High-density and high magnetic
Image
Correlation of seismic structure to gravity and magnetic profiles along the western half of SNORCLE line 1. The horizontal line at about 25 km is the approximate position of the Curie depth and is thus the approximate subsurface limit of magnetic response. Vertical lines are drawn from this depth to the magnetic profile where important magnetic anomalies are seen. Note the correlation of shallow structures to magnetic anomalies (e.g., at M1–M5). Vertical green lines are drawn from important gravity anomalies and correspond to deeper structures. FS1 and FS2, west and east peaks, respectively, of Fort Simpson anomaly; FS, Steamboat–Fraser trend. V.E., vertical exaggeration.

Correlation of seismic structure to gravity and magnetic profiles along the... Available to Purchase

Published: 23 September 2005
, respectively, of Fort Simpson anomaly; FS, SteamboatFraser trend. V.E., vertical exaggeration.
Image
(a) Unfiltered magnetic data of region near Steamboat–Fraser (SF) trend identified from gravity data. Note that the map includes a smaller area than the maps of Fig. 4 to facilitate comparisons. Arrows point to SF trend. (b) Directionally filtered magnetic data exhibiting little difference from the unfiltered data. (c) Unfiltered magnetic data overlain by a gray image of the gravity highs along the SF trend. Note that near profile 10 (P10), the magnetic highs appear to be offset to the east from the gravity trend.

( a ) Unfiltered magnetic data of region near SteamboatFraser (SF) trend i... Available to Purchase

Published: 10 January 2002
Fig. 5. ( a ) Unfiltered magnetic data of region near SteamboatFraser (SF) trend identified from gravity data. Note that the map includes a smaller area than the maps of Fig.  4 to facilitate comparisons. Arrows point to SF trend. ( b ) Directionally filtered magnetic data exhibiting little
Image
Isostatic and filtered isostatic gravity maps. (a) Isostatic gravity map of western Canada south of 66°N latitude (see Goodacre et al. 1987 for discussion of the isostatic anomaly calculations; Geological Survey of Canada 1999a). Note the large regional high throughout the Mackenzie Mountains (MMH), the values near zero in the southern Cordillera, and the high in the Rocky Mountains (RMH). Locations of new Lithoprobe seismic profiles (1, 2, and 3) are indicated in the north. (b) Directionally filtered isostatic gravity. The filter includes a low frequency filter and the filter azimuth is 065° relative to grid north (GN), rather than true north. Note the prominent Steamboat–Fraser trend (SF) that crosses the strike of surface structures. GSLsz, Great Slave Lake shear zone; CDF, Cordilleran deformation front; RMT, Rocky Mountain Trench; TT, Tintina Trench. The dashed line to the right of SF in the south is the Fraser River fault. Colour scale is the same as in (a).

Isostatic and filtered isostatic gravity maps. ( a ) Isostatic gravity map ... Available to Purchase

Published: 10 January 2002
and the filter azimuth is 065° relative to grid north (GN), rather than true north. Note the prominent SteamboatFraser trend (SF) that crosses the strike of surface structures. GSLsz, Great Slave Lake shear zone; CDF, Cordilleran deformation front; RMT, Rocky Mountain Trench; TT, Tintina Trench. The dashed line
Image
Models of the coincident gravity and magnetic data along profile 9 using a 2 3/4-D algorithm, because at this location the local magnetic anomaly is about 30° oblique to the Steamboat–Fraser trend (Fig. 4b). For modelling, the magnetic field parameters used were the following: average magnitude, 59 000 nT; average inclination, 70°; average declination –22°. (a) Model assuming a substantial component of the mass excess and magnetic material is concentrated in a narrow zone at depth. (b) Model assuming all of the mass excess and magnetic material is concentrated in a wide zone near the surface. Note that in either case, the relatively steep gradients in the magnetic profile require some near-surface magnetic material. k, magnetic susceptibility in SI units.

Models of the coincident gravity and magnetic data along profile 9 using a ... Available to Purchase

Published: 10 January 2002
Fig. 8. Models of the coincident gravity and magnetic data along profile 9 using a 2 3/4-D algorithm, because at this location the local magnetic anomaly is about 30° oblique to the SteamboatFraser trend (Fig.  4 b ). For modelling, the magnetic field parameters used were the following: average
Image
Comparison of (a) bandpass filtered isostatic gravity data (14–160 km wavelength), (b) magnetic data (Geological Survey of Canada 1999b), (c) directionally filtered gravity, and (d) outcrops of Tertiary volcanic rocks overlain on the filtered gravity (Wheeler and McFeely 1991). Arrows in (b) and (c) indicate the SF trend and are located in the same positions to facilitate comparisons between the magnetic and filtered gravity maps. Note that the magnetic high may be offset slightly from the gravity high near the southern part of the trend (near southern arrow in b and c; see also Fig. 5). P9 in (b) is the location of profile 9 used for modelling coincident magnetic and gravity profile. All 10 profile locations are shown in (d) with profile 1 (P1) in the north and profile numbers increasing to P10 in the south. The Rocky Mountain Trench (RMT) is dotted where it is primarily extensional (southern RMT) and dashed where it is primarily strike-slip (Tintina Trench and northern RMT). Region between the RMT and Cordilleran deformation front (CDF) is the Foreland Belt, and the dashed line in the south of the maps is the Fraser River fault. SF, Steamboat–Fraser trend; GSLsz, Great Slave Lake shear zone.

Comparison of ( a ) bandpass filtered isostatic gravity data (14–160 km wav... Available to Purchase

Published: 10 January 2002
it is primarily extensional (southern RMT) and dashed where it is primarily strike-slip (Tintina Trench and northern RMT). Region between the RMT and Cordilleran deformation front (CDF) is the Foreland Belt, and the dashed line in the south of the maps is the Fraser River fault. SF, SteamboatFraser trend; GSLsz
Image
Envelope (gray) of 10 profiles across the Steamboat–Fraser (SF) filtered gravity trend. The envelope was calculated by first aligning the profiles on the maximum value of the SF trend and then determining the maximum, minimum, and average values.

Envelope (gray) of 10 profiles across the SteamboatFraser (SF) filtered gr... Available to Purchase

Published: 10 January 2002
Fig. 6. Envelope (gray) of 10 profiles across the SteamboatFraser (SF) filtered gravity trend. The envelope was calculated by first aligning the profiles on the maximum value of the SF trend and then determining the maximum, minimum, and average values.
Image
Directionally filtered gravity data (northeast filter) with mapped faults overlain for a portion of the area of northeastern British Columbia. Note the spatial correlation of north-striking faults with the north-striking Steamboat–Fraser (SF) trend. These faults are associated with a deflection of structures that Thompson (1989) interpreted to be associated with a basement ramp. If so, the correlation with the SF potential field trend may be evidence that this trend is related to old (pre-Cordilleran) structures. CDF, Cordilleran Deformation Front; TT–NRMT, Tintina – Northern Rocky Mountain Trench.

Directionally filtered gravity data (northeast filter) with mapped faults o... Available to Purchase

Published: 23 September 2005
Fig. 7. Directionally filtered gravity data (northeast filter) with mapped faults overlain for a portion of the area of northeastern British Columbia. Note the spatial correlation of north-striking faults with the north-striking SteamboatFraser (SF) trend. These faults are associated
Journal Article

Tectonic significance of potential-field anomalies in western Canada: results from the Lithoprobe SNORCLE transect, Available to Purchase

C. Elissa Lynn, Frederick A. Cook, Kevin W. Hall
Published: 23 September 2005
Canadian Journal of Earth Sciences (2005) 42 (6): 1239–1255.
DOI: https://doi.org/10.1139/e05-037
...Fig. 3. Magnetic anomaly map of the same region as shown in Fig.  1 ( Geological Survey of Canada 1999 b ). GBma, Great Bear magmatic arc; SF, SteamboatFraser trend. Other abbreviations as in Figs.  1 and 2 . ...
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Journal Article

Correlative conformity or subtle unconformity? The distal expression of a sequence boundary in the Upper Cretaceous Mancos Shale, Henry Mountains Region, Utah, U.S.A. Available to Purchase

Zhiyang Li, Juergen Schieber
Published: 13 July 2022
Journal of Sedimentary Research (2022) 92 (7): 635–657.
DOI: https://doi.org/10.2110/jsr.2021.103
... by Heath (1977) for modern sediments and Bohacs et al. (2005) for ancient strata. Fig. 10.— Parasequence styles in A) FA1, B) FA2, C) FA3, and D) FA4. Parts A and C are from Steamboat. Parts B and D are from Salt Wash. The coarsening-upward trend of parasequences is indicated by blue...
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View PDF for article title, Correlative conformity or subtle unconformity? The distal expression of a sequence boundary in the Upper Cretaceous Mancos Shale, Henry Mountains Region, Utah, U.S.A.
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Journal Article

Screening for deep-marine reservoirs in frontier basins: Part 1—Examples from offshore mid-Norway Available to Purchase

Edith M. G. Fugelli, Tina R. Olsen
Journal: AAPG Bulletin
Published: 01 July 2005
AAPG Bulletin (2005) 89 (7): 853–882.
DOI: https://doi.org/10.1306/02110504029
... and soft-sediment deformation. Sediment stacking patterns are the result of deposition by high-density flows compensating for depositional topography. This can be seen on the location called Steamboat Rock, which is an outcrop consisting of massive, tabular sands with complex constructional terminations...
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View PDF for article title, Screening for deep-marine reservoirs in frontier basins: Part 1—Examples from offshore mid-Norway
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Journal Article

The Favona Epithermal Gold-Silver Deposit, Waihi, New Zealand Available to Purchase

Mark P. Simpson, Jeffrey L. Mauk
Journal: Economic Geology
Published: 01 August 2007
Economic Geology (2007) 102 (5): 817–839.
DOI: https://doi.org/10.2113/gsecongeo.102.5.817
..., Silverton, Gladstone, Union, Mascotte, and Amaranth were discovered less than 2 km east of the Martha deposit ( Bell and Fraser, 1912 ; Morgan, 1924 ). However, limited underground development of these veins between 1885 and 1902 produced only 4,376 kg of Au-Ag bullion from 70,491 t of ore, with most...
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View PDF for article title, The Favona Epithermal Gold-Silver Deposit, Waihi, New Zealand
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Journal Article

Potential for Events Similar to the Deadly West Salt Creek Landslide, Grand Mesa Area, Colorado Available to Purchase

Omid Arabnia, Paul Santi, Bennett Emmons, Emily Sparks
Published: 08 August 2024
Environmental & Engineering Geoscience (2024) 30 (3): 111–130.
DOI: https://doi.org/10.21663/EEG-D-23-00053
... . Madole, R. F. 1991 , Surficial Geologic Map of the Steamboat Springs 30′ × 60′ Quadrangle, Grand, Jackson, and Routt Counties, Colorado : U.S. Geological Survey Miscellaneous Investigations Series Map I-1825 . Marvin, R. F.; Mehnert, H. H.; and Mountjoy, W. M. 1966...
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View PDF for article title, Potential for Events Similar to the Deadly West Salt Creek Landslide, Grand Mesa Area, Colorado
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Journal Article

Hydrothermal Alteration at the Karangahake Epithermal Au-Ag Deposit, Hauraki Goldfield, New Zealand Available to Purchase

Mark P. Simpson, Michael F. Gazley, Alistair G.J. Stuart, Mark A. Pearce, Renee Birchall, Debra Chappell, Anthony B. Christie, Murray R. Stevens
Journal: Economic Geology
Published: 01 March 2019
Economic Geology (2019) 114 (2): 243–273.
DOI: https://doi.org/10.5382/econgeo.2019.4630
... ( Bell and Fraser, 1912 ). These lenses of less-altered rock are inferred to have a lower permeability that restricted fluid-mineral interaction, element exchange, and alteration by secondary minerals. The hard bars have low-rank clays (e.g., smectite or illite-smectite), compared to clays in surrounding...
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View PDF for article title, Hydrothermal Alteration at the Karangahake Epithermal Au-Ag Deposit, Hauraki Goldfield, New Zealand
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Journal Article

DIFFERENTIATING STYLES OF ALTERATION WITHIN KAOLIN-ALUNITE HYDROTHERMAL DEPOSITS OF ÇANAKKALE, NW TURKEY Available to Purchase

Hatice Ünal Ercan, Ö. Işik Ece, Paul A. Schroeder, Zekiye Karacik
Published: 01 June 2016
Clays and Clay Minerals (2016) 64 (3): 245–274.
DOI: https://doi.org/10.1346/CCMN.2016.0640305
... in a zone bounded by two NW–SE trending strike-slip faults ( Figure 2 ). It was exposed in four open pits between two fault zones (F1 and F2). The mineral assemblages of the deposits are similar, but their relative abundances differ (details are explained in the following sections). The four subdeposits...
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Journal Article

Hydrothermal Alteration and Hydrologic Evolution of the Golden Cross Epithermal Au-Ag Deposit, New Zealand Available to Purchase

Mark P. Simpson, Jeffrey L. Mauk, Stuart F. Simmons
Journal: Economic Geology
Published: 01 July 2001
Economic Geology (2001) 96 (4): 773–796.
DOI: https://doi.org/10.2113/gsecongeo.96.4.773
... of the Coromandel volcanic zone is controlled by north-northwest- and northeast- to east-northeast–trending block faults that formed in the Jurassic graywacke during the Early Cretaceous ( Skinner, 1986 , 1995 ). The Coromandel volcanic zone is bounded to the west by the Hauraki rift, a major graben filled by up...
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View PDF for article title, Hydrothermal Alteration and Hydrologic Evolution of the Golden Cross Epithermal Au-Ag Deposit, New Zealand
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Journal Article

Comparison of Epithermal Kaolin Deposits from the Etili Area (Çanakkale, Turkey): Mineralogical, Geochemical, and Isotopic Characteristics Available to Purchase

Hatice Ünal Ercan, Ö. Işık Ece, Emin Çiftçi, Ayça Aydın
Published: 01 October 2022
Clays and Clay Minerals (2022) 70 (5): 753–779.
DOI: https://doi.org/10.1007/s42860-022-00214-4
... important formations in these kaolin deposits occurred along the NE–SW-trending Çan-Etili-Bayramiç fault zone. The Bahadırlı, Duman, and Çaltıkara quarries are well preserved kaolin deposits throughout these fault zones located within the Çan Volcanics. Mineralogical, geochemical, and isotopic analyses were...
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View PDF for article title, Comparison of Epithermal Kaolin Deposits from the Etili Area (Çanakkale, Turkey): Mineralogical, Geochemical, and Isotopic Characteristics
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Book Chapter

Beyond Colorado’s Front Range—A new look at Laramide basin subsidence, sedimentation, and deformation in north-central Colorado Available to Purchase

Author(s)
James C. Cole, James H. Trexler, Jr., Patricia H. Cashman, Ian M. Miller, Ralph R. Shroba, Michael A. Cosca, Jeremiah B. Workman
Book: Through the Generations: Geologic and Anthropogenic Field Excursions in the Rocky Mountains from Modern to Ancient
Series: GSA Field Guide
Publisher: Geological Society of America
Published: 01 January 2010
DOI: 10.1130/2010.0018(03)
EISBN: 9780813756189
.... meeki (photo: Rick Wicker, DMNS). Figure 8. Schematic diagram showing profile of the modern Fraser River; elevations of highest remnants of the Troublesome Formation east of the Fraser River; elevation of base of Troublesome Formation penetrated in a drill hole; and topographic profile of pre...
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Abstract
View PDF for content titled, Beyond Colorado’s Front Range—A new look at Laramide basin subsidence, sedimentation, and deformation in north-central Colorado
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Abstract This field trip highlights recent research into the Laramide uplift, erosion, and sedimentation on the western side of the northern Colorado Front Range. The Laramide history of the North Park-Middle Park basin (designated the Colorado Headwaters Basin in this paper) is distinctly different from that of the Denver basin on the eastern flank of the range. The Denver basin stratigraphy records the transition from Late Cretaceous marine shale to recessional shoreline sandstones to continental, fluvial, marsh, and coal mires environments, followed by orogenic sediments that span the K-T boundary. Upper Cretaceous and Paleogene strata in the Denver basin consist of two mega-fan complexes that are separated by a 9 million-year interval of erosion/non-deposition between about 63 and 54 Ma. In contrast, the marine shale unit on the western flank of the Front Range was deeply eroded over most of the area of the Colorado Headwaters Basin (approximately one km removed) prior to any orogenic sediment accumulation. New 40 Ar- 39 Ar ages indicate the oldest sediments on the western flank of the Front Range were as young as about 61 Ma. They comprise the Windy Gap Volcanic Member of the Middle Park Formation, which consists of coarse, immature volcanic conglomerates derived from nearby alkalic-mafic volcanic edifices that were forming at about 6561 Ma. Clasts of Proterozoic granite, pegmatite, and gneiss (eroded from the uplifted at Laramide basin subsidence, sedimentation, and deformation in north-central Colorado, in Morgan, L.A., and Quane, S.L., eds., Through the Generations: core of the Front Range) seem to arrive in the Colorado Headwaters Basin at different times in different places, but they become dominant in arkosic sandstones and conglomerates about one km above the base of the Colorado Headwaters Basin section. Paleocurrent trends suggest the southern end of the Colorado Headwaters Basin was structurally closed because all fluvial deposits show a northward component of transport. Lacustrine depositional environments are indicated by various sedimentological features in several sections within the >3 km of sediment preserved in the Colorado Headwaters Basin, suggesting this basin may have remained closed throughout the Paleocene and early Eocene. The field trip also addresses middle Eocene(?) folding of the late Laramide basin-fill strata, related to steep reverse faults that offset the Proterozoic crystalline basement. Late Oligocene magmatic activity is indicated by dikes, plugs, and eruptive volcanic rocks in the Rabbit Ears Range and the Never Summer Mountains that span and flank the Colorado Headwaters Basin. These intrusions and eruptions were accompanied by extensional faulting along predominantly northwesterly trends. Erosion accompanied the late Oligocene igneous activity and faulting, leading to deposition of boulder conglomerates and sandstones of the North Park Formation and high-level conglomerates across the landscape that preserve evidence of a paleo-drainage network that drained the volcanic landscape.