(U-Th)/He chronology: Part 2. Considerations for evaluating, integrating, and interpreting conventional individual aliquot data

Flowers, Rebecca M.; Ketcham, Richard A.; Enkelmann, Eva; Gautheron, Cécile; Reiners, Peter W.; Metcalf, James R.; Danišík, Martin; Stöckli, Daniel F.; Brown, R. W.

doi:10.1130/b36268.1

Cited by 39 publications

(41 citation statements)

References 117 publications

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“…2B). The AHe ages predicted for these paths have variability that is ≤15% of the standard deviation of the mean age, which is well within the range that we define as "reproducible" for He thermochronometers (Flowers et al, 2015; see also Flowers et al, 2022). Path 2 yields ages of 31-52 Ma (18% variability).…”

Section: Grain [Eu] Composition Effectssupporting

confidence: 71%

“…The details of these examples are tailored to HeFTy's approach to searching tT space, to the fact that HeFTy inversion results are suites of individual tT histories that each fit the data, and to the important role of constraint boxes in controlling HeFTy model results. However, many of the approaches are applicable to other thermal history modeling programs and support other recent discussions of thermal history modeling practices (e.g., Fox and Carter, 2020;Flowers et al, 2022). We also emphasize that there are many appropriate approaches to handling thermal history modeling results; so, one's preferred method will depend on the data and modeling tools available as well as the geologic problem(s) of interest.…”

Section: ■ Strategies For and Examples Of Thermal History Modeling Us...mentioning

confidence: 63%

“…Thus, although there is general agreement about the importance of conducting tT modeling with careful consideration of thermochronometer kinetics, inversion algorithms, statistical methods, model design, data input, and geologic context, exactly how this should be done is extensively debated (e.g., Ketcham, 2018, 2020;Green and Duddy, 2021). Although valuable recommendations have been made about the reporting of modeling results (Flowers et al, 2015(Flowers et al, , 2016(Flowers et al, , 2022Gallagher, 2016), most thermochronologic studies do not provide explicit descriptions of their modeling practices and interpretation strategies. The absence of these details in the published literature means that many new and experienced modelers must reconstruct or reinvent modeling and interpretation strategies for themselves.…”

Section: ■ Introductionmentioning

confidence: 99%

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Thermal history modeling techniques and interpretation strategies: Applications using HeFTy

et al. 2022

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Advances in low-temperature thermochronology, and the wide range of geologic problems that it is used to investigate, have prompted the routine use of thermal history (time-temperature, tT) models to quantitatively explore and evaluate rock cooling ages. As a result, studies that investigate topics ranging from Proterozoic tectonics to Pleistocene erosion now commonly require a substantial numerical modeling effort that combines the empirical understanding of chronometer thermochemical behavior (kinetics) with independent knowledge or hypotheses about a study area’s geologic history (geologic constraints). Although relatively user-friendly programs, such as HeFTy and QTQt, are available to facilitate thermal history modeling, there is a critical need to provide the geoscience community with more accessible entry points for using these tools. This contribution addresses this need by offering an explicit discussion of modeling strategies in the program HeFTy. Using both synthetic data and real examples, we illustrate the opportunities and limitations of thermal history modeling. We highlight the importance of testing the sensitivity of model results to model design choices and describe a strategy for classifying model results that we call the Path Family Approach. More broadly, we demonstrate how HeFTy can be used to build an intuitive understanding of the thermochronologic data types and model design strategies that are capable of discriminating among geologic hypotheses.

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Section: Grain [Eu] Composition Effectssupporting

confidence: 71%

Section: ■ Strategies For and Examples Of Thermal History Modeling Us...mentioning

confidence: 63%

Section: ■ Introductionmentioning

confidence: 99%

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Thermal history modeling techniques and interpretation strategies: Applications using HeFTy

et al. 2022

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“…1 ). Different scenarios fit some results better at the expense of others, with data scatter stemming from imperfect knowledge of diffusion and annealing kinetics, and likely other factors influencing the results ( 4 ).…”

mentioning

confidence: 99%

“…Reducing the vast parameter space ( Fig. 1 , Right ) requires integrating critical geologic data in targeted localities ( 1 , 4 ) to discern the timing, magnitude, spatial extent, and mechanistic drivers of the Great Unconformities.…”

mentioning

confidence: 99%

Existing thermochronologic data do not constrain Snowball glacial erosion below the Great Unconformities

Flowers

Ketcham

Macdonald

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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Late Miocene–early Pliocene tectonic to erosional exhumation in the northwest of the Arabia–Eurasia collision zone

Madanipour

2023

Earth Surf Processes Landf

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The exhumation of actively deforming orogenic systems is commonly due to the incision of river systems in response to tectonically driven surface uplift. However, a regional base level and/or climatic variations can also cause erosional exhumation.The temporal and spatial distinction of the dominant mechanism during the topographic evolution of orogens is challenging. Using detailed morphological analyses and thermal modelling of an intrusive body through triple dating (zircon U-Pb, ZHe, and AHe), combined with the previously published structural, detrital, and bedrock low-temperature thermochronometry (apatite fission track and apatite helium) analysis, the transition from early Oligocene ($27 Ma) and middle Miocene ($12 Ma) tectonic exhumation to late Miocene-early Pliocene ($7-5 Ma) river incision and erosional exhumation in the Talesh Mountains in the NW of the Arabia-Eurasia collision zone was documented. The late Miocene-early Pliocene incision and the contemporaneous rapid exhumation documented in the Talesh Mountains are related to the base-level fall of the Caspian Sea due to its isolation from the Paratethys domain.The effect of this base-level fall then migrated to the margin of the Iranian Plateau and captured the overspilled basins ($4 Ma).

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(U-Th)/He chronology: Part 2. Considerations for evaluating, integrating, and interpreting conventional individual aliquot data

Cited by 39 publications

References 117 publications

Thermal history modeling techniques and interpretation strategies: Applications using HeFTy

Thermal history modeling techniques and interpretation strategies: Applications using HeFTy

Existing thermochronologic data do not constrain Snowball glacial erosion below the Great Unconformities

Late Miocene–early Pliocene tectonic to erosional exhumation in the northwest of the Arabia–Eurasia collision zone

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