Birth and evolution of the Virgin River fluvial system: ∼1 km of post–5 Ma uplift of the western Colorado Plateau

Walk, Cory J.; Karlstrom, Karl E.; Crow, Ryan S.; Heizler, Matthew T.

doi:10.1130/ges02019.1

Cited by 12 publications

(9 citation statements)

References 68 publications

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“…Using the published slip rate estimates of 0.44 to 0.57 mm yr −1 (Lund et al, 2007), this equates to vein formation depths from ∼ 40 to 300 m. However, this assumes negligible exhumation of the footwall over the last 540 ka, and they are minimum estimates. Using the local incision rate of the Virgin River through the footwall of 338 m Myr −1 (Walk et al, 2019) as a maximum estimate of footwall exhumation, this suggests a maximum depth of vein formation from 70 to 480 m. Consistent with the findings at thermal springs along the Hurricane fault zone (Crossey et al, 2006;Crossey et al, 2009;Nelson et al, 2009), this indicates that deeply circulated thermal fluids are moving up the fault zone, advecting deeper geotherms towards the surface, and mixing with shallow meteoric fluids. The relatively shallow depth of these processes is notable, and has been observed at other major normal faults.…”

Section: Implications Of Vein Geochronologysupporting

confidence: 65%

Spatiotemporal history of fault–fluid interaction in the Hurricane fault, western USA

Koger

Newell

2020

Solid Earth

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Abstract. The Hurricane fault is a ∼250 km long, west-dipping, segmented normal fault zone located along the transition between the Colorado Plateau and the Basin and Range tectonic provinces in the western USA. Extensive evidence of fault–fluid interaction includes calcite mineralization and veining. Calcite vein carbon (δ13CVPDB) and oxygen (δ18OVPDB) stable isotope ratios range from −4.5 ‰ to 3.8 ‰ and from −22.1 ‰ to −1.1 ‰, respectively. Fluid inclusion microthermometry constrains paleofluid temperatures and salinities from 45 to 160 ∘C and from 1.4 wt % to 11.0 wt % as NaCl, respectively. These data suggest mixing between two primary fluid sources, including infiltrating meteoric water (70±10 ∘C, ∼1.5 wt % NaCl, δ18OVSMOW ∼-10 ‰) and sedimentary brine (100±25 ∘C, ∼11 wt % NaCl, δ18OVSMOW ∼ 5 ‰). Interpreted carbon sources include crustal- or magmatic-derived CO2, carbonate bedrock, and hydrocarbons. Uranium–thorium (U–Th) dates from five calcite vein samples indicate punctuated fluid flow and fracture healing at 539±10.8 (1σ), 287.9±5.8, 86.2±1.7, and 86.0±0.2 ka in the upper 500 m of the crust. Collectively, data predominantly from the footwall damage zone imply that the Hurricane fault imparts a strong influence on the regional flow of crustal fluids and that the formation of veins in the shallow parts of the fault damage zone has important implications for the evolution of fault strength and permeability.

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Section: Implications Of Vein Geochronologysupporting

confidence: 65%

Spatiotemporal history of fault–fluid interaction in the Hurricane fault, western USA

Koger

Newell

2020

Solid Earth

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“…Detrital sanidine geochronology has the potential for utilization for many Phanerozoic sedimentary deposits (Copeland and Harrison, 1990;Chetel et al, 2011). Recent applications have mostly focused on Paleocene/Late Cretaceous chronostratigraphic studies and river terrace dating in the southwest United States (Hereford et al, 2016;Karlstrom et al, 2017;Leslie et al, 2018aLeslie et al, , 2018bAslan et al, 2019;Walk et al, 2019). The power of the method lies in the robustness of sanidine to produce ultraprecise and accurate dates by single-crystal total fusion.…”

Section: Detrital Sanidine 40 Ar/ 39 Ar Studiesmentioning

confidence: 99%

Interpreting and reporting 40Ar/39Ar geochronologic data

et al. 2020

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The 40Ar/39Ar dating method is among the most versatile of geochronometers, having the potential to date a broad variety of K-bearing materials spanning from the time of Earth’s formation into the historical realm. Measurements using modern noble-gas mass spectrometers are now producing 40Ar/39Ar dates with analytical uncertainties of ∼0.1%, thereby providing precise time constraints for a wide range of geologic and extraterrestrial processes. Analyses of increasingly smaller subsamples have revealed age dispersion in many materials, including some minerals used as neutron fluence monitors. Accordingly, interpretive strategies are evolving to address observed dispersion in dates from a single sample. Moreover, inferring a geologically meaningful “age” from a measured “date” or set of dates is dependent on the geological problem being addressed and the salient assumptions associated with each set of data. We highlight requirements for collateral information that will better constrain the interpretation of 40Ar/39Ar data sets, including those associated with single-crystal fusion analyses, incremental heating experiments, and in situ analyses of microsampled domains. To ensure the utility and viability of published results, we emphasize previous recommendations for reporting 40Ar/39Ar data and the related essential metadata, with the amendment that data conform to evolving standards of being findable, accessible, interoperable, and reusable (FAIR) by both humans and computers. Our examples provide guidance for the presentation and interpretation of 40Ar/39Ar dates to maximize their interdisciplinary usage, reproducibility, and longevity.

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“…Deposits from paleo-Lake Hualapai suggest the region immediately west of the Grand Wash fault was internally drained ca. 10-5.6 Ma (Lucchitta, 1966;Spencer et al, 2013;Faulds et al, 2016) and a major south-flowing drainage was established by 4.72 Ma (Walk et al, 2019). However, disruption of any transport across the fault likely began closer to the onset of fault motion ca.…”

Section: ■ Discussionmentioning

confidence: 99%

“…The Shivwits Plateau is a broad erosional surface cut across the Permian Kaibab Limestone north of the modern canyon that is bounded on the west by the Grand Wash fault. Preservation of geomorphic surfaces by Cenozoic volcanism displays a general southwest-to-northeast trend of escarpment retreat (Lucchitta, 1975(Lucchitta, , 1984(Lucchitta, , 1989Lucchitta and Jeanne, 2001), with remnants of Triassic Moenkopi Formation and later Mesozoic units preserved below capping resistant basalt flows, which follow the same southwest-to-northeast trend (Crow et al, 2011;Walk et al, 2019). South of the Hualapai and Coconino Plateaus is the transition zone of central Arizona, which separates the southwestern edge of the Colorado Plateau from the Basin and Range province.…”

Section: ■ Geologic Backgroundmentioning

confidence: 99%

A constraint on post–6 Ma timing of western Grand Canyon (Arizona, USA) incision removed: Local derivation indicated by ca. 5.4 Ma fluvial deposits below Shivwits Plateau basalts north of Grand Canyon

et al. 2021

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The timing of integration of the Colorado River system is central to understanding the landscape evolution of much of the southwestern United States. However, the time at which the Colorado River started incising the westernmost Grand Canyon (Arizona) is still an unsettled question, with conflicting interpretations of both geologic and thermochronologic data from western Grand Canyon. Fluvial gravels on the Shivwits Plateau, north of the canyon, have been reported to contain clasts derived from south of the modern canyon, suggesting the absence of western Grand Canyon at the time of their deposition. In this study, we reassess these deposits using modern geochronologic measurements to determine the age of the deposits and the presence or absence of clasts from south of the Grand Canyon. We could not identify southerly derived clasts, so cannot rule out the existence of a major topographic barrier such as Grand Canyon prior to the age of deposition of the gravels. 40Ar/39Ar analysis of a basalt clast entrained in the upper deposit (in combination with prior data) supports a maximum age of deposition of ca. 5.4 Ma, limiting deposition to post-Miocene, a period from which very few diagnostic and dated fluvial deposits remain in the western Colorado Plateau. Analysis of detrital zircon composition of the sand matrix supports interpretation of the deposit as being locally derived and not part of a major throughgoing river. We suggest that the published constraint of <6 Ma timing of Grand Canyon incision may be removed, given that no clasts that must be sourced from south of Grand Canyon were found in the only known outcrop of gravels under the Shivwits Plateau basalts at Grassy Mountain north of Grand Canyon.

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Birth and evolution of the Virgin River fluvial system: ∼1 km of post–5 Ma uplift of the western Colorado Plateau

Cited by 12 publications

References 68 publications

Spatiotemporal history of fault–fluid interaction in the Hurricane fault, western USA

Spatiotemporal history of fault–fluid interaction in the Hurricane fault, western USA

Interpreting and reporting 40Ar/39Ar geochronologic data

A constraint on post–6 Ma timing of western Grand Canyon (Arizona, USA) incision removed: Local derivation indicated by ca. 5.4 Ma fluvial deposits below Shivwits Plateau basalts north of Grand Canyon

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