Episodic Dissolution, Precipitation, and Slip along the Heart Mountain Detachment, Wyoming

Swanson, Erika; Wernicke, Brian P.; Hauge, Thomas A.

doi:10.1086/684253

Cited by 4 publications

(11 citation statements)

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“…An attempt was made to avoid large clasts when sampling, to aim for a more homogenous mixture of matrix material. The breccia varied widely from many meters thick and highly visible from up to 100 m away (e.g., Figure a) to under 1‐cm thick and barely detectable from 100 m away (Figure b; see also Swanson et al, ). Marble breccia (DET‐m) : These samples are exclusively from the unique basal cataclasite at White Mountain (Heart Mountain allochthon), where all of the hanging wall host is metamorphosed by local intrusions. These breccias were sampled from within 3 m of the detachment, but their distinctive appearance and proximity to metamorphic and magmatic features lead us to consider them separately from other detachment breccias (Figure c). Gouge (DET‐g for Mormon Mountains and HW‐g for Heart Mountain allochthon) : These samples are very fine‐grained cataclasites with no clasts visible, even with an optical microscope.…”

Section: Sample Texture Descriptionsmentioning

confidence: 90%

“…Only veins of at least 2‐mm width could supply enough material to analyze, limiting the number of these analyses. Detachment breccia (DET‐b) : These samples were all collected from within 1 m of the detachment surfaces (except ES12‐18, at 12 m below the detachment) and predominantly within 10 cm. They consist of a fine‐grained matrix and angular clasts (Figures a, c, and d), some of which appear to be clasts of an earlier brecciation episode Figure in Swanson et al, ). An attempt was made to avoid large clasts when sampling, to aim for a more homogenous mixture of matrix material.…”

Section: Sample Texture Descriptionsmentioning

confidence: 97%

“…We summarize these features below and show typical examples in Figures and . For more comprehensive structural characterization of these damage zones, including extensive documentation of features directly related to fluid flow such as veins and stylolites, we refer the reader to Anders et al (), Anderson et al (), Diehl et al (), and Swanson et al () for the Mormon Peak detachment and Anders et al () and Swanson et al () for the Heart Mountain detachment.…”

Section: Sample Texture Descriptionsmentioning

confidence: 99%

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Fluid Flow, Brecciation, and Shear Heating on Faults: Insights From Carbonate Clumped‐Isotope Thermometry

2018

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Slip on gently dipping detachments in the brittle crust has been enigmatic for decades, because fracture mechanics laws predict frictional resistance is too great for sliding to occur, except under rather unusual circumstances. The Miocene Mormon Peak detachment in Nevada and the Eocene Heart Mountain detachment in Wyoming are two well‐studied examples of upper crustal, carbonate‐hosted low‐angle detachments, with highly debated slip processes. Both low‐angle faults were active during regional magmatism, and a number of proposed slip mechanisms involve magmatic fluids, frictional heating, or both. To address the role that magmatic fluids and frictional heating may have played in reducing friction, we measured clumped‐isotope ratios on 137 carbonate samples from these faults. The majority of fault breccias and gouges on the detachment slip surface record temperatures that are colder than the host rock. Surprisingly, samples from within 5 m of the Heart Mountain detachment average just 65 °C, and not a single sample (out of 37 measurements, excluding metamorphosed host rock at White Mountain) records a temperature greater than 90 °C. Along both faults, most samples are depleted in δ18O relative to the host rock, indicating that meteoric, not magmatic, fluids were present and interacting with the fault rock. However, a few samples preserve temperatures of over 160 °C, which, based on textural and geochemical criteria, are difficult to explain other than by frictional heating during slip. These temperatures are recorded in one sample directly on the Mormon Peak detachment slip surface and in two hanging wall localities above the Heart Mountain detachment.

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Section: Sample Texture Descriptionsmentioning

confidence: 90%

Section: Sample Texture Descriptionsmentioning

confidence: 97%

Section: Sample Texture Descriptionsmentioning

confidence: 99%

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Fluid Flow, Brecciation, and Shear Heating on Faults: Insights From Carbonate Clumped‐Isotope Thermometry

2018

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“…Our approach is to present here a kinematic model based on reconstruction of the dismembered Mesozoic thrust system and does not depend on structural reconstruction of individual fault blocks in the Mormon Peak allochthon. Thus, although we acknowledge the central importance of fluid-assisted deformation in the development of the Mormon Peak and other carbonate allochthons (e.g., Swanson et al, 2012Swanson et al, , 2016, it is beyond the scope of this paper to address this important issue.…”

Section: Other Interpretations Of the Mormon Peak Detachmentmentioning

confidence: 99%

Geologic map of the east-central Meadow Valley Mountains, and implications for reconstruction of the Mormon Peak detachment, Nevada

Swanson

Wernicke

2017

Geosphere

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The role of low-angle faults in accommodating extension within the upper crust remains controversial because the existence of these faults markedly defies extant continuum theories of how crustal faults form, and once initiated, how they continue to slip. Accordingly, for many proposed examples, basic kinematic problems like slip direction, dip angle while active, and magnitude of offset are keenly debated. A well-known example is the Miocene Mormon Peak detachment and overlying Mormon Peak allochthon of southern Nevada (USA), whose origin and evolution have been debated for several decades. Here, we use geologic mapping in the Meadow Valley Mountains to help define the geometry and kinematics of emplacement of the Mormon Peak allochthon, the hanging wall of the Mormon Peak detachment. Pre-extension structural markers, inherited from the east-vergent Sevier thrust belt of Meso zoic age, are well suited to constrain the geometry and kine matics of the detachment. In this study, we add to these markers a newly mapped Sevier-age monoclinal flexure preserved in the hanging wall of the detachment. The bounding axial surfaces of the flexure can be readily matched to the base and top of the frontal Sevier thrust ramp, which is exposed in the footwall of the detachment to the east in the Mormon Mountains and Tule Springs Hills. Multiple proxies for the slip direction of the detachment, including the mean tilt direction of hanging wall fault blocks, the trend of striations measured on the fault plane, and other structural features, indicate that it is approximately S77°W (257°). Given the observed structural separation lines between the hanging wall and footwall, this slip direction indicates 12-13 km of horizontal displacement on the detachment (14-15 km net slip), lower than a previous estimate of 20-22 km, which was based on erroneous assumptions in regard to the geometry of the thrust system. Based on a new detailed map compilation of the region and recently published low-temperature thermochronologic data, palinspastic constraints also preclude earlier suggestions that the Mormon Peak allochthon is a composite of diachronously emplaced, surficial landslide deposits. Although earlier suggestions that the initiation angle of the detachment in the central Mormon Mountains is ~20°-25° remain valid, the geometry of the Sevier-age monocline in the Meadow Valley Mountains and other structural data suggest that the initial dip of the detachment steepens toward the north beneath the southernmost Clover Mountains, where the hanging wall includes kilometer-scale accumulations of volcanic and volcaniclastic strata.

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“…Generalized geologic map of the Heart Mountain slide area. Modified from Hauge (1993) and Malone et al (2014a). incremental movement potentially lasting millions of years (Hauge 1985(Hauge , 1990Templeton et al 1995;Swanson et al 2016), and catastrophic emplacement of Paleozoic carbonate and Eocene volcanic rocks over a period of minutes to hours (Craddock et al 2009). The mechanism of upper-plate movement that allows for catastrophic emplacement along a lowangle surface with only minor associated deformation preserved above, along, or below the detachment is poorly understood.…”

Section: Previous Workmentioning

confidence: 99%

Volcanic Initiation of the Eocene Heart Mountain Slide, Wyoming, USA

Malone

Craddock

Schmitz

et al. 2017

The Journal of Geology

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Additional information:Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. A B S T R A C TThe Eocene Heart Mountain slide of northwest Wyoming covers an area of as much as 5000 km 2 and includes allochthonous Paleozoic carbonate and Eocene volcanic rocks with a run-out distance of as much as 85 km. Recent geochronologic data indicated that the emplacement of the slide event occurred at ∼48.9 Ma, using laser ablation inductively coupled plasma mass spectrometry (LA-ICPMS) extracted from U-Pb zircon ages from basal layer and injectite carbonate ultracataclasite (CUC). We now refine that age with U-Pb results from a lamprophyre diatreme that is temporally and spatially related to the CUC injectites. The ages for the lamprophyre zircons are 48.97 5 0.36 Ma (LA-ICPMS) and 49.19 50.02 Ma (chemical abrasion isotope dilution thermal ionization mass spectrometry). Thus, the lamprophyre and CUC zircons are identical in age, and we interpret that the zircons in the CUC were derived from the lamprophyre during slide emplacement. Moreover, the intrusion of the lamprophyre diatreme provided the trigger mechanism for the Heart Mountain slide. Additional structural data are presented for a variety of calcite twinning strains, results from anisotropy of magnetic susceptibility for the lamprophyre and CUC injectites and alternating-field demagnetization on the lamprophyre, to help constrain slide dynamics. These data indicate that White Mountain experienced a rotation about a vertical axis and minimum of 357 of counterclockwise motion during emplacement.

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Episodic Dissolution, Precipitation, and Slip along the Heart Mountain Detachment, Wyoming

Cited by 4 publications

References 57 publications

Fluid Flow, Brecciation, and Shear Heating on Faults: Insights From Carbonate Clumped‐Isotope Thermometry

Fluid Flow, Brecciation, and Shear Heating on Faults: Insights From Carbonate Clumped‐Isotope Thermometry

Geologic map of the east-central Meadow Valley Mountains, and implications for reconstruction of the Mormon Peak detachment, Nevada

Volcanic Initiation of the Eocene Heart Mountain Slide, Wyoming, USA

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