Zircon U-Pb geochronology and Nd-Pb isotope geochemistry of Blue Ridge basement in the eastern Great Smoky Mountains, U.S.A.: Implications for the Proterozoic tectonic evolution of the southeastern Laurentian margin

IF 1.9 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
D. Moecher, F. C. Harris, E. A. Larkin, R. J. Quinn, K. B. Walsh, D. F. Loughry, Eric D. Anderson, S. Samson, A. Satkoski, E. Tohver
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引用次数: 4

Abstract

The Mesoproterozoic to Paleozoic history of the southeastern Laurentian margin involved repeated collisional and accretionary tectonomagmatic events that reworked and recycled older continental crust of preceding events. The Great Smoky Mountains Basement Complex (GSMBC) within the southern Appalachian Blue Ridge exposes complexly deformed orthogneiss and paragneiss that preserve a record of Laurentian margin evolution from ca. 1.9 Ga to 450 Ma. The GSMBC consists primarily of: (1) 1.34 to 1.31 Ga (pre-Elzevirian) granodioritic orthogneiss and entrained mafic xenoliths that represent some of the oldest crust in Appalachian Grenville massifs (correlated with pre-Elzevirian crustal components in the Adirondack, Green Mountains, New Jersey Highlands, and French Broad massifs), (2) ca. l.15 to 1.05 Ga augen and granitic orthogneiss produced during Shawinigan and Ottawan phases of Grenville-age magmatism and metamorphism, respectively, and (3) paragneiss derived from protoliths with either Grenville-age (1.1–1.0 Ga) or post-Grenville (Neoproterozoic) depositional ages based on presence/absence of ca. 1.0 Ga metamorphic zircon and 1.9 to 1.1 Ga detrital zircon. All lithologies experienced Taconian metamorphism and variable migmatization. Pre-Ottawan paragneiss exhibits major detrital zircon ages modes at 2.0 to 1.6 and 1.4 to 1.3 Ga that require a component of older Proterozoic crust in the sediment source region. Detrital zircon grains in post-Ottawan paragneiss exhibits the full spectrum of Grenville-age modes that correlate with the five phases of Grenville magmatic/metamorphic events in eastern Laurentia. These paragneiss samples also contain scattered 750 to 600 Ma detrital zircon grains that constrain their maximum depositional age to late Neoproterozoic. The sedimentary protoliths of the latter paragneiss consist largely of detritus from exhumation of all Grenville crustal age components during post-orogenic exhumation and crustal extension leading up to Late Neoproterozoic breakup of Rodinia. Most zircon U-Pb age systematics exhibit variable discordance that can be attributed to disturbance of the U-Pb system and/or new zircon growth during either high-grade Ottawan (ca. 1.04 Ga) or Taconian (ca. 0.46 Ga) regional metamorphism and migmatization. Neodymium TDM model ages for granodioritic orthogneiss and paragneiss range from 1.8 to 1.6 Ga, indicating that the rocks were derived from recycling of Proterozoic crust (that is, they are not juvenile), consistent with the 1.9 to 1.6 Ga detrital zircon grains in pre-Ottawan paragneiss and with 1.8 to 1.7 Ga inherited zircon in some 1.33 Ga orthogneisses and a 1.35 Ga xenolith. Whole rock Pb isotope compositions of GSMBC rocks overlap the field of compositions characteristic of Amazonian crust and of other basement rocks from the south-central Appalachians. The Pb isotopes and geochronology in orthogneiss, mafic xenoliths, and pre-Ottawan paragneiss are consistent with a correlation of the GSMBC with the Mars Hill terrane within the French Broad massif and with the greater Grenvillian south-central Appalachian basement (SCAB) that is considered exotic to Laurentia, and transferred during Rodinian collision prior to ca. 1.2 Ga. Similarities in protolith ages and Pb isotopes point to the Paraguá terrane of Amazonia (southwestern Brazil and eastern Bolivia) as a likely match for SCAB. Initial Amazonia-Laurentia collision occurred at ca. 1.35 to 1.32 Ga with final transfer of SCAB to Laurentia occurring after 1.20 Ga within the sinistral oblique collision zone between Laurentia and Amazonia defined by previous workers.
美国大烟山东部蓝岭基底锆石U-Pb地质年代和Nd-Pb同位素地球化学:对劳伦东南缘元古代构造演化的启示
劳伦斯东南部边缘的中元古代至古生代历史涉及反复的碰撞和增生构造岩浆事件,这些事件改造和再循环了先前事件的旧大陆地壳。阿巴拉契亚蓝岭南部的大烟山基底复合体(GSMBC)暴露出复杂变形的正片麻岩和副片麻岩,保存了约1.9 Ga至450 Ma的劳伦期边缘演化记录。GSMBC主要由:(1)1.34至1.31 Ga(前埃尔泽韦里阶)花岗闪长质正片麻岩和夹带的镁铁质捕虏体组成,代表阿巴拉契亚-格伦维尔地块中一些最古老的地壳(与阿迪朗达克、青山、新泽西高地和法国布罗德地块中的前埃尔泽维里阶地壳成分相关),(2)分别在Grenville时代岩浆作用和变质作用的Shawinigan和Ottawan阶段产生的约l.15至1.05 Ga的眼球状和花岗质正片麻岩,以及(3)源自Grenwille时代(1.1–1.0 Ga)或后Grenville(新元古代)沉积时代的原岩的副片麻岩,基于存在/不存在约1.0 Ga的变质锆石和1.9至1.1 Ga的碎屑锆石。所有岩性都经历了塔康变质作用和可变混合岩化作用。前Ottawan副片麻岩显示出2.0至1.6和1.4至1.3 Ga的主要碎屑锆石年龄模式,这需要沉积物源区中较老元古代地壳的成分。Ottawan后副片麻岩中的碎屑锆石颗粒显示出全谱的Grenville年龄模式,这些模式与Laurentia东部的Grenvville岩浆/变质事件的五个阶段相关。这些副片麻岩样品还含有分散的750至600 Ma碎屑锆石颗粒,这些颗粒将其最大沉积年龄限制在新元古代晚期。后副片麻岩的沉积原岩主要由造山后剥露和地壳伸展过程中所有Grenville地壳年龄组分剥露的碎屑组成,导致罗迪尼亚新元古代晚期断裂。大多数锆石U-Pb年龄系统显示出可变的不一致性,这可归因于高级Ottawan(约1.04 Ga)或Taconian(约0.46 Ga)区域变质作用和混合岩化期间U-Pb系统的扰动和/或新锆石的生长。花岗闪长质正片麻岩和副麻岩的钕TDM模型年龄范围为1.8-1.6 Ga,表明这些岩石来源于元古代地壳的再循环(即它们不是新生的),与前Ottawan副麻岩中的1.9~1.6 Ga碎屑锆石颗粒一致,与一些1.33 Ga正麻岩和1.35 Ga捕虏体中的1.8-1.7 Ga继承锆石一致。GSMBC岩石的全岩Pb同位素组成与亚马逊地壳和阿巴拉契亚中南部其他基岩的组成特征重叠。正片麻岩、镁铁质捕虏体和前Ottawan副片麻岩中的Pb同位素和地质年代与GSMBC与French Broad地块内的Mars Hill地体以及被认为是Laurentia外来的大格伦维尔期阿巴拉契亚中南部基底(SCAB)的相关性一致,并在约1.2 Ga之前的罗迪尼亚碰撞期间转移。原岩年龄和Pb同位素的相似性表明,亚马逊(巴西西南部和玻利维亚东部)的Paraguá地体可能与SCAB相匹配。最初的Amazonia-Laurentia碰撞发生在约1.35至1.32 Ga,SCAB向Laurentia的最终转移发生在1.20 Ga之后,在Laurentia和Amazonia之间的左旋斜碰撞带内,由先前的工作人员定义。
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来源期刊
American Journal of Science
American Journal of Science 地学-地球科学综合
CiteScore
5.80
自引率
3.40%
发文量
17
审稿时长
>12 weeks
期刊介绍: The American Journal of Science (AJS), founded in 1818 by Benjamin Silliman, is the oldest scientific journal in the United States that has been published continuously. The Journal is devoted to geology and related sciences and publishes articles from around the world presenting results of major research from all earth sciences. Readers are primarily earth scientists in academia and government institutions.
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