Zircon (U‐Th)/He thermochronology of Neoproterozoic strata from the Mackenzie Mountains, Canada: Implications for the Phanerozoic exhumation and deformation history of the northern Canadian Cordillera

Powell, J. W.; Schneider, David; Stöckli, Daniel F.; Fallas, K M

doi:10.1002/2015tc003989

Cited by 50 publications

(46 citation statements)

References 88 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Understanding sources of intrasample dispersion in grain cooling ages is important for evaluating uncertainties in thermochronometric interpretations and optimizing sampling design. Most samples in this study displayed greater dispersion in ZHe grain ages (typical 1σ ~10% of mean age) than expected for analytical uncertainty (~4% of grain age), similar to results of other studies (e.g., Wolfe & Stockli, ; Guenthner et al, ; Powell et al, ; Ault et al, ), partly related to varying radiation damage that affects He diffusion (Guenthner et al, ). Grains were selected for ZHe analysis based on similar eU contents (mostly 30 to 300 ppm) and U‐Pb ages (mostly 2.0–1.0 Ga), and thus similar values of maximum accumulated radiation damage.…”

Section: Discussionsupporting

confidence: 89%

Fault Slip and Exhumation History of the Willard Thrust Sheet, Sevier Fold‐Thrust Belt, Utah: Relations to Wedge Propagation, Hinterland Uplift, and Foreland Basin Sedimentation

et al. 2019

View full text Add to dashboard Cite

Zircon (U‐Th)/He (ZHe) and zircon fission track thermochronometric data for 47 samples spanning the areally extensive Willard thrust sheet within the western part of the Sevier fold‐thrust belt record enhanced cooling and exhumation during major thrust slip spanning approximately 125–90 Ma. ZHe and zircon fission track age‐paleodepth patterns along structural transects and age‐distance relations along stratigraphic‐parallel traverses, combined with thermo‐kinematic modeling, constrain the fault slip history, with estimated slip rates of ~1 km/Myr from 125 to 105 Ma, increasing to ~3 km/Myr from 105 to 92 Ma, and then decreasing as major slip was transferred onto eastern thrusts. Exhumation was concentrated during motion up thrust ramps with estimated erosion rates of ~0.1 to 0.3 km/Myr. Local cooling ages of approximately 160–150 Ma may record a period of regional erosion, or alternatively an early phase of limited (<10 km) thrust slip. Propagation of the Sevier wedge front and major thrust slip during the late Early to mid‐Cretaceous were synchronous with increasing subsidence and deposition of thick synorogenic strata in the foreland, crustal thickening in the hinterland, growing igneous activity in the Sierran magmatic arc, and increasing plate convergence rates. Along‐strike, other parts of the Cordilleran retroarc fold‐thrust belt also experienced major shortening during the late Early to mid‐Cretaceous, following a period of earlier Cretaceous quiescence. Late Jurassic shortening was concentrated nearer the arc, and thus mostly in the hinterland at the latitude of northern Utah, related to width and location of the passive‐margin sedimentary wedge relative to the plate margin.

show abstract

Section: Discussionsupporting

confidence: 89%

Fault Slip and Exhumation History of the Willard Thrust Sheet, Sevier Fold‐Thrust Belt, Utah: Relations to Wedge Propagation, Hinterland Uplift, and Foreland Basin Sedimentation

et al. 2019

View full text Add to dashboard Cite

show abstract

“…Nonetheless, the two scenarios are so similar that the current calibration of the Guenthner et al () model does not allow us to differentiate between them. It is important to stress that here we have reached the model's limitations emanating from its parameterization requirements, as already detected by previous authors (Powell et al, ; Vacherat et al, ). We note that this model cannot simulate the older ages of our data set for any thermal history with maximum temperatures during rifting (120–95 Ma in simulations) higher than 190 °C (e.g., scenarios 4, 5, 9, 10, 14, and 15).…”

Section: Discussionsupporting

confidence: 74%

“…This result also clearly illustrates the difficulty in identifying a single t ‐ T history using ZHe ages plotted against eU. As recently noted by some authors in other geologic settings (Anderson et al, ; Johnson et al, ; Powell et al, ; Vacherat et al, ), forward modeling suggests that the damage‐dependent model of diffusion is able to reproduce only qualitatively, not quantitatively, the range of single‐grain ZHe ages and both positive and negative age‐eU correlations. This probably also explains the failure of the HeFTy software to produce plausible thermal histories when performing inverse modeling with too many input data.…”

Section: Discussionsupporting

confidence: 58%

“…The most recent, rapid cooling history of a sample or a group of samples is dated at opposite ends of the eU concentration spectrum, irrespective of any earlier history. Any earlier thermal histories shape age‐eU correlations for maximum predicted ages and constrain any positive and/or negative correlation trends for these older ages (referred to as the ZHe inheritance curve; Guenthner et al, ; Powell et al, ). This point is illustrated with some sensitivity tests in Figures S5 and S6 and will be discussed below.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Thermochronological Evidence of Early Orogenesis, Eastern Pyrenees, France

et al. 2019

Self Cite

View full text Add to dashboard Cite

In collisional orogens, distinguishing the thermal signature of early orogenesis from the preceding rift or from subsequent thermal events is a major challenge. We present an integrated geological and low‐temperature thermochronology study of the Paleozoic Agly‐Salvezines crustal block in the retrowedge of the eastern Pyrenees (France). The northern Pyrenees preserves one of the best geological records of a rift‐to‐collision transition. The Agly‐Salvezines block represents the inverted distal European margin of an Aptian–Cenomanian rift system. Seventeen samples were collected throughout the external orogenic massif and analyzed for low‐temperature thermochronology: zircon (U‐Th)/He dating documents the cooling history of the massif during the initiation and early phase of Pyrenean convergence, while apatite (U‐Th)/He dating completes the record of plate collision. Using inverse and forward modeling of new low‐temperature thermochronology data, we show that the Pyrenean retrowedge records two clear phases of orogenic cooling, Late Campanian–Maastrichtian and Ypresian–Bartonian, which we relate to early inversion of the distal rifted margin and main collision, respectively. An earlier, late Aptian–Turonian cooling history is detected, possibly related to rifting and/or postrift. No cooling is evidenced during the Paleocene during which tectonic quiescence is recorded in the adjacent Aquitaine retroforeland basin. Using our low‐temperature thermochronology data and geological constraints, we propose a crustal‐scale sequentially restored model for the tectonic and thermal transition from extension to peak orogenesis in the eastern Pyrenees, which suggests that both thrusting and underplating processes contributed to early inversion of the Aptian–Cenomanian rift system.

show abstract

“…Advances in (U‐Th)/He thermochronology provide new potential to address this problem. The strong influence of radiation damage on the He retentivity of apatite, zircon, and titanite means that (U‐Th)/He data for these phases can be used to decipher cooling through wide temperature ranges (e.g., Baughman et al, ; Flowers et al, ; Gautheron et al, ; Guenthner et al, ; Orme et al, ; Powell et al, ; Shuster et al, ). For example, zircon and titanite (U‐Th)/He (ZHe, THe) closure temperatures (T c ) can vary by up to 180°C owing to this effect (Guenthner et al, ; Baughman et al, ).…”

Section: Introductionmentioning

confidence: 99%

Deciphering a 2 Gyr‐Long Thermal History From a Multichronometer (U‐Th)/He Study of the Phalaborwa Carbonatite, Kaapvaal Craton, South Africa

Baughman

Flowers

2018

Geochem Geophys Geosyst

View full text Add to dashboard Cite

(U‐Th)/He data were obtained for four minerals (baddeleyite‐BHe, titanite‐THe, zircon‐ZHe, apatite‐AHe) from the 2.06 Ga Phalaborwa carbonatite complex and nearby Archean basement of the Kaapvaal craton, South Africa. Our goals are to evaluate the relative He temperature sensitivities of these phases, better understand how radiation damage and other factors affect them, and inform aspects of the craton's thermal history. BHe dates overlap with Phalaborwa emplacement and record the highest temperatures of the dated phases. THe dates are 700–1,100 Ma and display a limited negative date‐eU correlation. ZHe dates are negatively correlated with eU, are younger (561–32 Ma) and have higher eU than the THe data, with the highest‐eU grains younger than the AHe dates. AHe dates are reproducible with a mean of 107 ± 7 Ma. The THe and ZHe data show radiation damage reduction of their He retentivities manifested as the negative date‐eU correlations. Alpha dose estimates for zircon are several orders of magnitude higher than for titanite, consistent with the ZHe dates recording lower temperatures and a younger portion of the history than the THe dates. Thermal history modeling yields time‐temperature paths that (1) explain the AHe, ZHe, and THe data while honoring existing geologic constraints, thus demonstrating the internal consistency of the data set, (2) imply possible reheating during Namaqua‐Natal orogenesis, and (3) limit maximum probable temperatures to ∼180°C during 300–183 Ma Karoo basin burial. The results show that exploiting multiple (U‐Th)/He thermochronometers and radiation damage effects can provide new insights into long‐term craton evolution.

show abstract

Zircon (U‐Th)/He thermochronology of Neoproterozoic strata from the Mackenzie Mountains, Canada: Implications for the Phanerozoic exhumation and deformation history of the northern Canadian Cordillera

Cited by 50 publications

References 88 publications

Fault Slip and Exhumation History of the Willard Thrust Sheet, Sevier Fold‐Thrust Belt, Utah: Relations to Wedge Propagation, Hinterland Uplift, and Foreland Basin Sedimentation

Fault Slip and Exhumation History of the Willard Thrust Sheet, Sevier Fold‐Thrust Belt, Utah: Relations to Wedge Propagation, Hinterland Uplift, and Foreland Basin Sedimentation

Thermochronological Evidence of Early Orogenesis, Eastern Pyrenees, France

Deciphering a 2 Gyr‐Long Thermal History From a Multichronometer (U‐Th)/He Study of the Phalaborwa Carbonatite, Kaapvaal Craton, South Africa

Contact Info

Product

Resources

About