In situ Rb-Sr dating of slickenfibres in deep crystalline basement faults

Tillberg, Mikael; Drake, Henrik; Zack, Thomas; Kooijman, Ellen; Whitehouse, Martin J.; Åström, Mats E.

doi:10.1038/s41598-019-57262-5

Cited by 52 publications

(51 citation statements)

References 58 publications

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“…The events started with Paleoproterozoic mylonitization followed by Mesoproterozoic, Neoproterozoic, Silurian-Carboniferous, Permian, and Jurassic fracture reactivation, featuring successively lower formation temperatures of the fracture coating minerals [23,[34][35][36]39,57,58]. Fracture reactivation was related to far-field orogenic events [57,59], as confirmed by high spatial resolution Rb/Sr and/or U-Pb dating of both slickenfibre minerals [36], veins [34], and bulk sample 40 Ar/ 39 Ar dating [39,60]. Bulk sample 87 Sr/ 86 Sr analysis has shown an overall evolution from low values of Proterozoic calcite veins (from~0.7070) to much higher ratios (up to~0.7175-0.7185) in coatings of calcite in currently open and water-conducting fractures [23,32,61].…”

Section: Forsmark and Laxemar-äspö-sites For Sampling Of Ancient Calcmentioning

confidence: 99%

“…We connect the calcite Sr isotope compositions with those of modern groundwater to determine whether the youngest of these calcite growth zones could be precipitated from the present-day waters. We compare and link the distinguished generations with published geochronological constraints [34,[36][37][38][39] of the same fracture assemblage to assess the overall temporal span of the precipitation history in presently water-conducting fractures. We also investigate the 87 Sr/ 86 Sr variability of modern calcite precipitated from fracture water in a borehole at 415 m depth over the course of 17 years, and compare these 87 Sr/ 86 Sr values with the modern source water.…”

Section: Introductionmentioning

confidence: 99%

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Using 87Sr/86Sr LA-MC-ICP-MS Transects within Modern and Ancient Calcite Crystals to Determine Fluid Flow Events in Deep Granite Fractures

2020

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The strontium isotope signature (87Sr/86Sr) of calcite precipitated in rock fractures and faults is a frequently used tool to trace paleofluid flow. However, bedrock fracture networks, such as in Precambrian cratons, have often undergone multiple fracture reactivations resulting in complex sequences of fracture mineral infillings. This includes numerous discrete calcite crystal overgrowths. Conventional 87Sr/86Sr analysis of dissolved bulk samples of such crystals is not feasible as they will result in mixed signatures of several growth zonations. In addition, the zonations are too fine-grained for sub-sampling using micro-drilling. Here, we apply high spatial resolution 87Sr/86Sr spot analysis (80 µm) in transects through zoned calcite crystals in deep Paleoproterozoic granitoid fractures using laser ablation multi-collector inductively coupled plasma mass spectrometry (LA-MC-ICP-MS) to trace discrete signs of paleofluid flow events. We compare the outermost calcite growth zone with 87Sr/86Sr values of the present-day groundwater sampled in the same boreholes to distinguish potential modern precipitates. We then connect our results to previously reported radiometric dating and C and O isotope signatures to understand the temporal history and physicochemical evolution of fluid flow within the fractures. Comparisons of modern calcite precipitated in a borehole over a period of 17 years with modern waters prove the concept of using 87Sr/86Sr as a marker for fluid origin in this environment and for how 87Sr/86Sr changed during marine water infiltration. Intermittent calcite precipitation over very long time spans is indicated in calcite of the currently open fractures, showing an evolution of 87Sr/86Sr from ~0.705–0.707—a population dated to ~1.43 billion years—to crystal overgrowth values at ~0.715–0.717 that overlap with the present-day groundwater values. This shows that high spatial resolution Sr isotope analysis of fine-scaled growth zonation within single calcite crystals is applicable for tracing episodic fluid flow in fracture networks.

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Section: Forsmark and Laxemar-äspö-sites For Sampling Of Ancient Calcmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Using 87Sr/86Sr LA-MC-ICP-MS Transects within Modern and Ancient Calcite Crystals to Determine Fluid Flow Events in Deep Granite Fractures

2020

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“…Following the work of Zack and Hogmalm (2016) and Hogmalm et al (2017) for assessing the most suitable reaction cell gases, several publications have attempted to solve geological problems using the in situ Rb-Sr technique (Şengün et al, 2019;Tillberg et al, 2017;Tillberg et al, 2020). All these studies, except the one from Tillberg et al (2020), identified only a single age population within individual samples, which could have been resolved (at higher precision) with solution Rb-Sr or 40 Ar/ 39 Ar. Tillberg et al (2020) observed multiple age populations in their samples, but these were from mineral separates and the textural context was not preserved.…”

Section: Introductionmentioning

confidence: 99%

“…All these studies, except the one from Tillberg et al (2020), identified only a single age population within individual samples, which could have been resolved (at higher precision) with solution Rb-Sr or 40 Ar/ 39 Ar. Tillberg et al (2020) observed multiple age populations in their samples, but these were from mineral separates and the textural context was not preserved. To date, no published study has taken full advantage of the spatial resolving power of the in situ Rb-Sr technique whilst retaining textural context.…”

Section: Introductionmentioning

confidence: 99%

Resolving multiple geological events using in situ Rb-Sr geochronology: implications for metallogenesis at Tropicana, Western Australia

Olierook¹,

Rankenburg²,

Ulrich³

et al. 2020

Preprint

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Abstract. Dating multiple geological events in single samples using thermochronology and geochronology is relatively common but it is only with the recent advent of triple quadrupole LA-ICP-MS that in situ Rb-Sr dating has become a more commonly applied and powerful tool to date K- and Rb-bearing minerals. Here, we date, for the first time, two generations of mineral assemblages in individual thin sections using the in situ Rb-Sr method. Two distinct mineral assemblages, both probably associated with Au mineralization, are identified in samples from the Tropicana gold mine in the Albany–Fraser Orogen, Western Australia. For Rb-Sr purposes, the key dateable minerals are two generations of biotite, and additional phengite associated with the second assemblage. Our results reveal that the first, coarse-grained generation of biotite grains records a minimum age of 2535 ± 18 Ma, coeval with previous 40Ar/39Ar biotite, Re-Os pyrite and U-Pb rutile results. The second, fine-grained and recrystallized generation of biotite grains record an age of 1207 ± 12 Ma across all samples. Phengite and muscovite yielded broadly similar results at ca. 1.2 Ga but data is overdispersed for a single coeval population of phengite and shows elevated age uncertainties for muscovite. We propose that the ca. 2530 Ma age recorded by various geochronometers represents cooling and exhumation, and that the age of ca. 1210 Ma is related to major shearing associated with the regional deformation associated with Stage II of the Albany–Fraser Orogeny. This is the first time that an age of ca. 1210 Ma has been identified in the Tropicana Zone, which may have ramifications for constraining the timing of mineralization in the region. The in situ Rb-Sr technique is currently the only tool capable of resolving both geological events in these rocks.

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“…Fault histories are also important for building regional tectonic frameworks, understanding ore genesis, forming basin evolution models, and studying seismically active faults that pose geohazards and engineering challenges (e.g., Zwingmann et al, 2010). Fault timing is typi-cally constrained through cross-cutting relationships, but is more precisely achieved by direct dating of fault-generated materials such as fault gouge, slip-surface hematite, opal, pseudotachylyte, and slickenfibers (Nuriel et al, 2012(Nuriel et al, , 2019aTagami, 2012;Ault et al, 2015;Tillberg et al, 2020).…”

Section: Dating Brittle Faultsmentioning

confidence: 99%

Syncing fault rock clocks: Direct comparison of U-Pb carbonate and K-Ar illite fault dating methods

Mottram¹,

Kellett

Barresi³

et al. 2020

Geology

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The timing of slip on brittle faults in Earth’s upper crust is difficult to constrain, and direct radiometric dating of fault-generated materials is the most explicit approach. Here we make a direct comparison between K-Ar dating of fault gouge clay (authigenic illite) and U-Pb dating of carbonate slickenfibers and veins from the same fault. We have dated fault generated materials from the Big Creek fault, a northwest-striking, dextral strike-slip fault system in Yukon Territory, Canadian Cordillera. Both methods yielded dates at ca. 73 Ma and ca. 60–57 Ma, representing at least two periods of fault slip that form part of a complex fault and fluid-flow history. The Cretaceous result lies within previous indirect estimates for major slip on the fault. The Paleocene–Eocene result coincides with the estimated timing of slip of the nearby Tintina and Denali faults, which are crustal-scale, northwest-striking dextral faults, indicating Big Creek fault reactivation during regional faulting. The coincidence of periods of carbonate-crystallizing fracturing and fluid flow with intervals of seismic, gouge-generating slip supports the fault valve model, where fault strength is mediated by fluid pressures, and fluid emplacement requires seismic pumping in otherwise impermeable aseismic fault zones. The reproducibility of slip periods for distinct fault-generated materials using different decay systems indicates that these methods provide complimentary results and can be reliably applied to date brittle fault slip, opening new opportunities for investigating fault conditions with associated mineralizing fluid events.

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In situ Rb-Sr dating of slickenfibres in deep crystalline basement faults

Cited by 52 publications

References 58 publications

Using 87Sr/86Sr LA-MC-ICP-MS Transects within Modern and Ancient Calcite Crystals to Determine Fluid Flow Events in Deep Granite Fractures

Using 87Sr/86Sr LA-MC-ICP-MS Transects within Modern and Ancient Calcite Crystals to Determine Fluid Flow Events in Deep Granite Fractures

Resolving multiple geological events using in situ Rb-Sr geochronology: implications for metallogenesis at Tropicana, Western Australia

Syncing fault rock clocks: Direct comparison of U-Pb carbonate and K-Ar illite fault dating methods

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