6 research outputs found
Paleoproterozoic source contributions to the São Roque Group sedimentation: LA-MC-ICPMS U-Pb dating and Sm-Nd systematics of clasts from metaconglomerates of the Boturuna Formation
The São Roque Group is characterized by volcano-sedimentary sequences, in which deposition probably started in the late Paleoproterozoic. U-Pb dating by LA-MC-ICPMS of zircons extracted from predominantly equigranular monzogranites clasts from Morro Doce and Morro do Polvilho regions, yield paleoproterozoic ages of 2199 ± 8.5 Ma and 2247 ± 13 Ma, respectively. These represent the ages for the main source of granite for the metaconglomerates from the Boturuna Formation (basal unit of São Roque Group). Its polycyclic history is reinforced by the presence of inherited Archean zircons (2694 ± 29 Ma) found within the clasts. Moreover, these clasts have also been affected by the Neoproterozoic overprinting event as indicated by their lower intercept Concordia ages. Sm-Nd isotope data for the main clast varieties from the Morro Doce metaconglomerates yield T DM ages of 2.6 to 2.7 Ga, demonstrating that these granites are the recycling products of an Archean crustal component. The metaconglomerate arkosean framework yields slightly lower εNd(t) values than those for the clasts, indicating that a younger and/or more primitive source also contributed to the Boturuna Formation.O Grupo São Roque é caracterizado por uma sequência vulcanossedimentar com deposição provavelmente iniciada no Paleoproterozoico tardio. Datações U-Pb obtidas por LA-MC-ICPMS de zircões extraídos das variedades predominantes dos clastos de monzogranitos equigranulares, das regiões do Morro Doce e Morro do Polvilho, mostram idades paleoproterozoicas de 2199 ± 8,5 Ma e 2247 ± 13 Ma, respectivamente. Estas representam as idades da principal fonte de granito da Formação Boturuna (unidade basal do Grupo São Roque). A história policíclica deste domínio é reforçada pela presença de zircões arqueanos herdados (2694 ± 29 Ma), encontrados nos clastos. Além disso, tais clastos também foram afetados pelo evento Neoproterozoico, conforme indicado pelo intercepto inferior das idades concórdia. Dados isotópicos Sm-Nd para os principais clastos do metaconglomerado do Morro Doce têm idades T DM entre 2,6 a 2,7 Ga, demonstrando que estes granitos são produtos da reciclagem de um componente crustal arqueano. O arcabouço dos metaconglomerados, quando comparado com os clastos, mostra valores mais baixos de εNd(t), indicando contribuições de fontes mais jovens e/ou primitivas para a Formação Boturuna
Paleoproterozoic source contributions to the São Roque Group sedimentation: LA-MC-ICPMS U-Pb dating and Sm-Nd systematics of clasts from metaconglomerates of the Boturuna Formation
The So Roque Group is characterized by volcano-sedimentary sequences, in which deposition probably started in the late Paleoproterozoic. U-Pb dating by LA-MC-ICPMS of zircons extracted from predominantly equigranular monzogranites clasts from Morro Doce and Morro do Polvilho regions, yield paleoproterozoic ages of 2199 8.5 Ma and 2247 13 Ma, respectively. These represent the ages for the main source of granite for the metaconglomerates from the Boturuna Formation (basal unit of So Roque Group). Its polycyclic history is reinforced by the presence of inherited Archean zircons (2694 29 Ma) found within the clasts. Moreover, these clasts have also been affected by the Neoproterozoic overprinting event as indicated by their lower intercept Concordia ages. Sm-Nd isotope data for the main clast varieties from the Morro Doce metaconglomerates yield TDM ages of 2.6 to 2.7 Ga, demonstrating that these granites are the recycling products of an Archean crustal component. The metaconglomerate arkosean framework yields slightly lower ENd(t) values than those for the clasts, indicating that a younger and/or more primitive source also contributed to the Boturuna Formation
Depositional timing of Neoarchean turbidites of the Slave craton - recommended nomenclature and type localities
Two temporally distinct Neoarchean turbidite packages are known to occur in the Slave craton. The older is a greywacke-mudstone succession that includes the renowned Burwash Formation (ca. 2661 Ma). In this study, a previously undated tuff bed is demonstrated to have crystallized at ca. 2650.5 Âą 1.0 Ma refining the deposition age of these turbidites between ca. 2661 and 2650 Ma. The younger turbidites are locally distinctive as they contain interstratified banded iron formation (BIF). Previous work demonstrated that the younger turbidites were deposited between ca. 2640 to 2615 Ma, based entirely on maximum depositional ages from detrital zircons. A ~3-cm-thick felsic-to-intermediate tuff bed was discovered interbedded with these BIF-bearing turbidites. The tuff bed contains a single age population of zircon with a crystallization age of 2620 Âą 6 Ma defining the depositional timing of these BIF-bearing turbidites.
New U-Pb detrital zircon dates from extensive turbidite sequences in the eastern and central part of the Slave craton are also presented. We use the new and previously published results to recommend nomenclature for these extensive sedimentary rocks in the Slave craton. The ca. 2661 to 2650 Ma turbidites remain part of the previously ascribed Duncan Lake Group. The younger ca. 2620 Ma turbidites are assigned to the new Slemon Group. Where robust age-data exist, we recommend formation names and include type localities for each.The accepted manuscript in pdf format is listed with the files at the bottom of this page. The presentation of the authors' names and (or) special characters in the title of the manuscript may differ slightly between what is listed on this page and what is listed in the pdf file of the accepted manuscript; that in the pdf file of the accepted manuscript is what was submitted by the author
Recommendations for the reporting and interpretation of isotope dilution U-Pb geochronological information
U-Pb geochronology by isotope dilution−thermal ionization mass spectrometry (ID-TIMS) has the potential to be the most precise and accurate of the deep time chronometers, especially when applied to high-U minerals such as zircon. Continued analytical improvements have made this technique capable of regularly achieving better than 0.1% precision and accuracy of dates from commonly occurring high-U minerals across a wide range of geological ages and settings. To help maximize the long-term utility of published results, we present and discuss some recommendations for reporting ID-TIMS U-Pb geochronological data and associated metadata in accordance with accepted principles of data management. Further, given that the accuracy of reported ages typically depends on the interpretation applied to a set of individual dates, we discuss strategies for data interpretation. We anticipate that this paper will serve as an instructive guide for geologists who are publishing ID-TIMS U-Pb data, for laboratories generating the data, the wider geoscience community who use such data, and also editors of journals who wish to be informed about community standards. Combined, our recommendations should increase the utility, veracity, versatility, and “half-life” of ID-TIMS U-Pb geochronological data.</p