Tracking 40 Million Years of Migrating Magmatism across the Idaho Batholith Using Zircon U-Pb Ages and Hf Isotopes from Cretaceous Bentonites

Hannon, Jeffrey S.; Dietsch, Craig; Huff, Warren D.; Garway, Davidson

doi:10.3390/min11091011

Cited by 3 publications

(4 citation statements)

References 67 publications

(137 reference statements)

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“…The U-Pb system is extremely resistant to thermal overprinting (>900 • C; [22]) and is, therefore, unaffected by thermal events when the most suitable mineral, zircon, is analyzed. These advantages and improvements in the technology of LA-ICP-MS made it a rapid, precise and accurate method for U-Pb geochronology which has recently been extended [23][24][25][26][27][28][29][30][31][32]. The combination of U-Pb and FT methods could provide insights on history of the provenance that has undergone metamorphism.…”

Section: Introductionmentioning

confidence: 99%

Combined Zircon/Apatite U-Pb and Fission-Track Dating by LA-ICP-MS and Its Geological Applications: An Example from the Egyptian Younger Granites

et al. 2021

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Laser Ablation-Inductively Coupled Plasma-Mass Spectrometry (LA-ICP-MS) is classically used in U-Pb dating to measure U and Pb isotopic concentrations. Recently, it has become frequently used in fission-track (FT) chronometry too. As an advantage, the U-Pb and FT double dating will enable efficiently determining the crystallization ages and the thermo-tectonic history concurrently as samples volume, analytical time, efforts, and cost will be greatly reduced. To demonstrate the validity of this approach, a Younger granite (Ediacaran age) sample from North Eastern Desert (NED), Egypt was analyzed for U-Pb and FT double dating. The integration of multiple geochronologic data yielded a zircon U-Pb crystallization age of 599 ± 30 Ma, after emplacement, the rock cooled /uplifted rapidly to depths of 9–14 km as response to the post-Pan African Orogeny erosional event as indicated by apatite U-Pb age of 474 ± 9 Ma. Afterwards, the area experienced a slow cooling/exhumation for a short period, most-likely as response to denudation effect. During the Devonian, the area was rapidly exhumed to reach depths of 1.5–3 km as response to the Hercynian tectonic event, as indicated by a zircon FT age of 347 ± 16 Ma. Then the studied sample has experienced a relatively long period of thermal stability between the Carboniferous and the Eocene. During the Oligocene-Miocene, the Gulf of Suez opening event affected the area by crustal uplift to its current elevation. This integration of Orogenic and thermo-tectonic information reveals the validity, efficiency, and importance of double dating of U-Pb and FT techniques using LA-ICP-MS methodology.

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Section: Introductionmentioning

confidence: 99%

Combined Zircon/Apatite U-Pb and Fission-Track Dating by LA-ICP-MS and Its Geological Applications: An Example from the Egyptian Younger Granites

et al. 2021

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“…This potential high‐flux magmatic episode of the Idaho batholith is based on inheritance of 100–85 Ma ages in the 83–67 Ma Atlanta peraluminous suite of the Idaho batholith (Gaschnig, Vervoort, et al., 2017), the documentation of voluminous magmatism and high‐grade metamorphism in central Idaho (Ma et al., 2021), and DZ age spectra from marine strata in the Bighorn Basin, Wyoming (May et al., 2013); the age of this proposed magmatic flux is strikingly similar to the apparent magmatic flux curve for the Sierra Nevada batholith (Ducea, 2001). More recently, work primarily in the Bighorn Basin, which focused on U‐Pb zircon geochronology of marine bentonite beds, has also documented magmatism between 100 and 85 Ma (Hannon et al., 2020, 2021). These recent studies are consistent with—and refine—previous interpretations based on DZ age spectra (May et al., 2013) because the primary source for zircon grains in bentonites of the Bighorn Basin was interpreted as ash‐fall derived from the Idaho batholith based on age and trace element geochemistry (Hannon et al., 2020, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…More recently, work primarily in the Bighorn Basin, which focused on U‐Pb zircon geochronology of marine bentonite beds, has also documented magmatism between 100 and 85 Ma (Hannon et al., 2020, 2021). These recent studies are consistent with—and refine—previous interpretations based on DZ age spectra (May et al., 2013) because the primary source for zircon grains in bentonites of the Bighorn Basin was interpreted as ash‐fall derived from the Idaho batholith based on age and trace element geochemistry (Hannon et al., 2020, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…The ∼15 m.y. spread of ages within the <100 Ma fraction may be explained by the presence of xenocrystic zircons (Gaschnig, Vervoort, et al., 2017; Hannon et al., 2021), or by incorporation of older portions of the volcanic stratigraphy during explosive eruptions (Schwartz et al., 2021). We interpret that during eruption, the older volcanic cover would have been incorporated into the eruptive material and settled as ash‐fall in the nonmarine Idaho‐Montana sector of the foreland basin system.…”

Section: Discussionmentioning

confidence: 99%

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Timing of the Transition From Sevier‐ to Laramide‐Style Tectonism in Southwestern Montana Based on the Provenance of the Frontier Formation, North American Cordillera

et al. 2023

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The Upper Cretaceous Frontier Formation in southwestern Montana is coeval with the transition from Sevier‐ to Laramide‐style tectonism in the Idaho‐Montana sector of the North American Cordillera. To better constrain the timing of initial exhumation above the Laramide‐style Blacktail‐Snowcrest arch, we use biostratigraphic data, sandstone petrography, and detrital zircon (DZ) geochronology to determine the provenance and depositional age of the Frontier Formation. Near Lima Peaks, erosion of Lower Cretaceous strata from the frontal Sevier‐style Tendoy thrust sheet provided sediment to the foreland basin. In the Western Centennial Mountains, sediment sources included those same sources as well as Neoproterozoic and Cambrian strata and Mesoproterozoic plutons in the Belt basin. In contrast, near the Gravelly Range, sediment eroded from Pennsylvanian‐Upper Cretaceous strata atop the Blacktail‐Snowcrest basement‐cored uplift, documenting unroofing to Pennsylvanian‐Permian stratigraphic levels by 87–85 Ma. Palynology corroborates recycling into the Frontier Formation, including from the underlying Blackleaf Formation. The ubiquitous presence of 100–85 Ma DZ ages coupled with different interpreted source regions suggests that an ash‐fall source contributed young zircon grains to the Frontier Formation. The timing of exhumation above the Blacktail‐Snowcrest arch provided by these new data presented herein suggest that Laramide‐style tectonism in Idaho‐Montana may be unrelated to shallow‐angle subduction within a narrow corridor as envisioned by current models. Instead, upper plate controls, such as the locations of inherited faults and basement highs, the distribution and thickness of pre‐orogenic sedimentary cover, and the availability of detachment surfaces, may be responsible for Laramide‐style tectonism during early Late Cretaceous time.

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U–Pb–Hf and morphological evolution of zircon from granites associated with world-class tungsten skarn deposits in the northern Canadian Cordillera

Rasmussen,

Falck,

Luo

et al. 2024

Lithos

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Tracking 40 Million Years of Migrating Magmatism across the Idaho Batholith Using Zircon U-Pb Ages and Hf Isotopes from Cretaceous Bentonites

Cited by 3 publications

References 67 publications

Combined Zircon/Apatite U-Pb and Fission-Track Dating by LA-ICP-MS and Its Geological Applications: An Example from the Egyptian Younger Granites

Combined Zircon/Apatite U-Pb and Fission-Track Dating by LA-ICP-MS and Its Geological Applications: An Example from the Egyptian Younger Granites

Timing of the Transition From Sevier‐ to Laramide‐Style Tectonism in Southwestern Montana Based on the Provenance of the Frontier Formation, North American Cordillera

U–Pb–Hf and morphological evolution of zircon from granites associated with world-class tungsten skarn deposits in the northern Canadian Cordillera

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