Detrital Zircon Uranium-lead Geochronology and Hafnium-isotope Analyses of Passive Margin and Roberts Mountains Allochthon Strata PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Detrital Zircon Uranium-lead Geochronology and Hafnium-isotope Analyses of Passive Margin and Roberts Mountains Allochthon Strata PDF full book. Access full book title Detrital Zircon Uranium-lead Geochronology and Hafnium-isotope Analyses of Passive Margin and Roberts Mountains Allochthon Strata by Gwen Margaret Linde. Download full books in PDF and EPUB format.
Author: Gwen Margaret Linde
Publisher:
ISBN:
Category : Electronic books
Languages : en
Pages : 360
Get Book Here
Book Description
This dissertation investigated Neoproterozoic–Devonian units of the western Laurentian passive margin and Roberts Mountains allochthon (RMA) and determined U-Pb detrital ages and Hf isotope zircon analyses that provide new insights into the early Paleozoic tectonics of western Laurentia. The three chapters investigate several difficult questions and contradictions in the understanding of early Paleozoic tectonism in western Laurentia through analysis of sedimentary units. The provenance, depositional histories, and tectonic evolution of the lower Paleozoic sedimentary strata of north-central Nevada have long been subjects of speculation and debate. Detrital zircon U-Pb geochronology and Hf-isotope analyses indicate the provenance, sedimentary distribution patterns, and tectonic evolution of Upper Neoproterozoic–Cambrian passive margin strata and Ordovician–Devonian strata of the RMA, with a special emphasis on the enigmatic Harmony Formation. The study reported in Chapter 1 uses detrital zircon U-Pb geochronology to determine whether or not the Upper Neoproterozoic–Lower Cambrian Osgood Mountain Quartzite and the Upper Cambrian–Lower Ordovician Preble Formation in the Osgood Mountains of northern Nevada were units of the western Laurentian passive margin. Within the Osgood Mountain Quartzite, U-Pb age populations of the detrital zircons shift with stratal age. This shift indicates that the zircons were shed in different proportions from the source terranes, which suggests a change in provenance within the Osgood Mountain Quartzite. These changes are consistent across a Great Basin transect of coeval passive margin strata. The change in provenance is due to a shift in sedimentary transport patterns, which was caused by the Late Neoproterozoic-Early Cambrian uplift of the Transcontinental Arch. This study provided independent corroboration of the existence of the Transcontinental Arch and better precision for the timing at which the Arch uplifted. The study also recorded the impact of the uplifted Arch on continent-wide sediment dispersal patterns—the change in predominant source terranes—and confirmed the Arch as a sediment source for passive-margin strata. Regional coeval changes in detrital zircon U-Pb age patterns provide a correlative tool in unfossiliferous sediments and could be useful in future studies. Chapter 2 describes how detrital zircon U-Pb geochronology and Hf-isotope analyses were used to determine the provenance, sedimentary transport, and tectonic evolution of RMA strata. Workers have speculated for decades, with little agreement, on the origin, depositional basin(s), and subsequent tectonic transport of the RMA. Zircon grains from six Ordovician to Devonian arenite samples were analyzed for U-Pb ages; approximately one-quarter of these grains were further analyzed for Hf isotope ratios. Five of the studied units have similar U-Pb age populations and Hf-isotope ratios, while the U-Pb ages and Hf-ratios of the Ordovician lower Vinini Formation are significantly different. Comparison of these data with known analyses of igneous basement rocks and other sedimentary units of Laurentia reveals that the lower Vinini Formation originated in the north-central Laurentian craton. The other five units, as well as Ordovician passive margin sandstones of the western Laurentian margin, had a common source in the Peace River Arch region of western Canada. All of the RMA strata were deposited near the Peace River Arch region and subsequently tectonically transported south along the Laurentian margin, from where they were emplaced onto the craton during the Antler orogeny. This study determined the origin, location of the depositional basin, and proposed a subsequent tectonic evolution that accounts for origin, deposition, and current location of the RMA strata. Chapter 3 describes the origin, age, and tectonic development of the Harmony Formation. The Harmony Formation has always been difficult to explain—it is mostly an immature feldspathic arenite, which would argue for minimal transport from origin to deposition. However, its general position as the top thrust plate in the RMA stack argues for deposition oceanward of other more texturally mature RMA strata. The age of the Harmony Formation is equally contentious—published age determinations range from Cambrian to Mississippian. Zircon grains from ten arenite samples were analyzed for U-Pb ages; grains from eight of these samples were further analyzed for Hf-isotope ratios. Seven of the arenite units have similar U-Pb age peaks and Hf isotope ratios, whereas three differ significantly. The data confirmed the subdivision of the Harmony Formation into two petrofacies, quartzose (Harmony A) and feldspathic (Harmony B). Harmony A originated in the central Laurentian craton. Harmony B had a common source in eastern Alberta–western Saskatchewan, north of the source of the Harmony A. All of the Harmony Formation strata were deposited near eastern Alberta in Late Neoproterozoic through Cambrian time and subsequently tectonically interleaved with the Roberts Mountains allochthon strata. The entire package was tectonically transported south along the Laurentian margin. Subsequently, it was emplaced eastward onto the craton during the Late Devonian to Early Mississippian Antler orogeny. This study proposed a reasonable solution to one of the longest enduring and most puzzling conundrums of the western Cordillera—the origin, age, and transport of the Harmony Formation. These three studies demonstrated the utility of detrital zircon U-Pb geochronology and Hf-isotope analyses in better understanding difficult sedimentary and tectonic problems. The studies also provided new insights into the Early Paleozoic tectonic evolution of western Laurentian.
Author: Gwen Margaret Linde
Publisher:
ISBN:
Category : Electronic books
Languages : en
Pages : 360
Get Book Here
Book Description
This dissertation investigated Neoproterozoic–Devonian units of the western Laurentian passive margin and Roberts Mountains allochthon (RMA) and determined U-Pb detrital ages and Hf isotope zircon analyses that provide new insights into the early Paleozoic tectonics of western Laurentia. The three chapters investigate several difficult questions and contradictions in the understanding of early Paleozoic tectonism in western Laurentia through analysis of sedimentary units. The provenance, depositional histories, and tectonic evolution of the lower Paleozoic sedimentary strata of north-central Nevada have long been subjects of speculation and debate. Detrital zircon U-Pb geochronology and Hf-isotope analyses indicate the provenance, sedimentary distribution patterns, and tectonic evolution of Upper Neoproterozoic–Cambrian passive margin strata and Ordovician–Devonian strata of the RMA, with a special emphasis on the enigmatic Harmony Formation. The study reported in Chapter 1 uses detrital zircon U-Pb geochronology to determine whether or not the Upper Neoproterozoic–Lower Cambrian Osgood Mountain Quartzite and the Upper Cambrian–Lower Ordovician Preble Formation in the Osgood Mountains of northern Nevada were units of the western Laurentian passive margin. Within the Osgood Mountain Quartzite, U-Pb age populations of the detrital zircons shift with stratal age. This shift indicates that the zircons were shed in different proportions from the source terranes, which suggests a change in provenance within the Osgood Mountain Quartzite. These changes are consistent across a Great Basin transect of coeval passive margin strata. The change in provenance is due to a shift in sedimentary transport patterns, which was caused by the Late Neoproterozoic-Early Cambrian uplift of the Transcontinental Arch. This study provided independent corroboration of the existence of the Transcontinental Arch and better precision for the timing at which the Arch uplifted. The study also recorded the impact of the uplifted Arch on continent-wide sediment dispersal patterns—the change in predominant source terranes—and confirmed the Arch as a sediment source for passive-margin strata. Regional coeval changes in detrital zircon U-Pb age patterns provide a correlative tool in unfossiliferous sediments and could be useful in future studies. Chapter 2 describes how detrital zircon U-Pb geochronology and Hf-isotope analyses were used to determine the provenance, sedimentary transport, and tectonic evolution of RMA strata. Workers have speculated for decades, with little agreement, on the origin, depositional basin(s), and subsequent tectonic transport of the RMA. Zircon grains from six Ordovician to Devonian arenite samples were analyzed for U-Pb ages; approximately one-quarter of these grains were further analyzed for Hf isotope ratios. Five of the studied units have similar U-Pb age populations and Hf-isotope ratios, while the U-Pb ages and Hf-ratios of the Ordovician lower Vinini Formation are significantly different. Comparison of these data with known analyses of igneous basement rocks and other sedimentary units of Laurentia reveals that the lower Vinini Formation originated in the north-central Laurentian craton. The other five units, as well as Ordovician passive margin sandstones of the western Laurentian margin, had a common source in the Peace River Arch region of western Canada. All of the RMA strata were deposited near the Peace River Arch region and subsequently tectonically transported south along the Laurentian margin, from where they were emplaced onto the craton during the Antler orogeny. This study determined the origin, location of the depositional basin, and proposed a subsequent tectonic evolution that accounts for origin, deposition, and current location of the RMA strata. Chapter 3 describes the origin, age, and tectonic development of the Harmony Formation. The Harmony Formation has always been difficult to explain—it is mostly an immature feldspathic arenite, which would argue for minimal transport from origin to deposition. However, its general position as the top thrust plate in the RMA stack argues for deposition oceanward of other more texturally mature RMA strata. The age of the Harmony Formation is equally contentious—published age determinations range from Cambrian to Mississippian. Zircon grains from ten arenite samples were analyzed for U-Pb ages; grains from eight of these samples were further analyzed for Hf-isotope ratios. Seven of the arenite units have similar U-Pb age peaks and Hf isotope ratios, whereas three differ significantly. The data confirmed the subdivision of the Harmony Formation into two petrofacies, quartzose (Harmony A) and feldspathic (Harmony B). Harmony A originated in the central Laurentian craton. Harmony B had a common source in eastern Alberta–western Saskatchewan, north of the source of the Harmony A. All of the Harmony Formation strata were deposited near eastern Alberta in Late Neoproterozoic through Cambrian time and subsequently tectonically interleaved with the Roberts Mountains allochthon strata. The entire package was tectonically transported south along the Laurentian margin. Subsequently, it was emplaced eastward onto the craton during the Late Devonian to Early Mississippian Antler orogeny. This study proposed a reasonable solution to one of the longest enduring and most puzzling conundrums of the western Cordillera—the origin, age, and transport of the Harmony Formation. These three studies demonstrated the utility of detrital zircon U-Pb geochronology and Hf-isotope analyses in better understanding difficult sedimentary and tectonic problems. The studies also provided new insights into the Early Paleozoic tectonic evolution of western Laurentian.
Author: Nancy Chen
Publisher:
ISBN:
Category :
Languages : en
Pages : 308
Get Book Here
Book Description
Author: Charles Ryan Jeffcoat
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Get Book Here
Book Description
Author: T.-L. Knudsen
Publisher:
ISBN:
Category :
Languages : en
Pages :
Get Book Here
Book Description
Author: John Laurence Kulp
Publisher:
ISBN:
Category : Geochemistry
Languages : en
Pages : 428
Get Book Here
Book Description
Author: U.S. Department of the Interior
Publisher: CreateSpace
ISBN: 9781497466807
Category : Reference
Languages : en
Pages : 52
Get Book Here
Book Description
This report presents the results of zircon uranium-lead geochronologic analysis of 24 rock samples collected and analyzed in support of the "Bedrock Geologic Map of Vermont" by Ratcliff and others. The samples in this study were collected from mapped exposures identified while conducting either new, detailed geologic quadrangle mapping or reconnaissance mapping, both of which were used for compilation of the bedrock geologic map of Vermont.
Author: Kylie J. Matonia
Publisher:
ISBN: 9781741682717
Category : Geochronometry
Languages : en
Pages : 81
Get Book Here
Book Description
Author: U.S. Department of the Interior
Publisher: CreateSpace
ISBN: 9781499255904
Category : Reference
Languages : en
Pages : 50
Get Book Here
Book Description
This report presents the results of zircon uranium-lead geochronologic analyses of 24 rock samples collected and analyzed in support of the "Bedrock Geological Map of Vermont" by Ratcliffe and others (in press).
Author: Ralph Smyser Cannon
Publisher:
ISBN:
Category : Isotope geology
Languages : en
Pages : 14
Get Book Here
Book Description
Author: Xiaoping Xia
Publisher:
ISBN: 9781361237694
Category :
Languages : en
Pages :
Get Book Here
Book Description
This dissertation, "Spot U-Pband Hf Isotope Analyses of Detrital Zircons From the Khondalites in the Western Block of the North China Craton" by Xiaoping, Xia, 夏小平, was obtained from The University of Hong Kong (Pokfulam, Hong Kong) and is being sold pursuant to Creative Commons: Attribution 3.0 Hong Kong License. The content of this dissertation has not been altered in any way. We have altered the formatting in order to facilitate the ease of printing and reading of the dissertation. All rights not granted by the above license are retained by the author. Abstract: Abstract of thesis entitled SPOT U-Pb AND Hf ISOTOPE ANALYSES OF DETRITAL ZIRCONS FROM THE KHONDALITES IN THE WESTERN BLOCK OF THE NORTH CHINA CRATON Submitted by Xiaoping Xia for the degree of Doctor of Philosophy at The University of Hong Kong in August 2005 A major advancement of Precambrian geology in the North China Craton has been achieved by its tectonic subdivision into the Eastern and Western Blocks separated by the Trans-North China Orogen. However, further understanding the history of this craton is hindered by the lack of data for the Ordos Terrane, which is covered by basin sediments in the southern part of the Western Block. The khondalites in the Western Block are high-grade metasedimentary rocks derived from the Ordos Terrane. Therefore, detrital zircon U-Pb and Hf isotope studies for these khondalites will provide insights into the basement nature of this terrane. The spot U-Pb isotope analytical procedure on zircon is developed in this study by using a frequency-quintupled Nd: YAG 213 nm UV laser ablation system coupled to a VG PQExcel mass spectrometer and successfully applied to the study of the detrital zircons from the khondalites in Jining, Wulashan and Luliang Complexes. Most of the detrital zircons are igneous origin and yield U-Pb ages of 1.9-2.1 Ga, indicating a dominating Paleoproterozoic provenance. The khondalites have a maximum depositional age of 1.84 Ga and were metamorphised 1.81 Ga ago, demonstrating that they were deposited in Paleoproterozoic and soon metamorphosed due to the assembly of the North China Craton.. Hf isotope data for detrital zircons from the Wulashan Complex show that they possess ε values between -8 and +9, suggesting their crystallization from Hf magmas derived from underlying old crust and juvenile materials from the mantle. The lowest ε values with different ages define an evolution line that Hf intersects the depleted mantle line at 2.6 Ga in a ε vs. time diagram. This Hf implies that the sedimentary provenance was underlain by a lower crust separated from the mantle at 2.6 Ga. All the detrital zircons from one sample have 2.0 Ga ages and positive ε from +1 to +9, recording a significant crustal Hf growth event. Hf isotope data for the Luliang Complex support that the sedimentary provenance was mainly underlain by a lower crust extracted from the mantle at 2.6 Ga with significant juvenile crustal addition at 2.1 Ga. The oldest crustal material was identified to have an age of 4.2 Ga, demonstrating the existence of an older component in the deep crust of the Ordos Terrane or alternatively imply that the Luliang khondalites in the Trans-North China Orogen IIcame from a provenance different from that of the Khondalite Belt in the Western Block. Above results suggest that the Ordos Terrane of the Western Block may have early Archean nuclei that underwent a major crustal accretion from the mantle at 2.6 Ga and a significant juvenile crustal growth at 2.0-2.1 Ga. This is in striking contrast with the Eastern Block, which has two crustal growth peaks at 3.6-3.2 Ga and 3.0-2.6 Ga, and 2.8 Ga is the dominant time for crustal formation. These data clearly demonstrate that the Eastern and Western Blocks evolved separately before they collided to form the coherent North China Craton at 1.8 Ga. III DOI: 10.5353/th_b3577369 Subjects: Zircon - China Isotope
