美国维吉尼亚州丁威迪地体彼得斯堡基的重新定义及其地壳继承意义

IF 1.7 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
Geosphere Pub Date : 2023-04-20 DOI:10.1130/ges02546.1
M. Carter, R. McAleer, C. Holm-Denoma, M. Occhi, B. E. Owens, J. Vazquez
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引用次数: 0

摘要

宾夕法尼亚-二叠纪彼得斯堡岩基的变质火成岩的野外关系以及地球化学和岩石学研究确定了至少两种不同的岩石类型:片理变质花岗片麻岩和块状到斑岩花岗岩。主要由花岗闪长岩组成的叶状变花岗质片麻岩在地球化学上与伴生的块状和斑状花岗质岩石截然不同。这些片麻岩产生的辐射年龄从425 Ma到403 Ma不等,并证明许多属于晚古生代彼得堡岩基的岩石比复合岩基最年轻的部分要早100 Ma,并且是早期基础结构地体的一部分。弗吉尼亚州彼得堡西南部的两个块状等粒花岗岩样品的产年约为321 Ma和317 Ma,比弗吉尼亚州里士满附近的斑状花岗岩、块状花岗岩和二黄长石的约300 Ma年龄要早15-20 Ma。地质填图表明,彼得堡西南的早宾夕法尼亚花岗岩与里士满附近的晚宾夕法尼亚至早二叠世花岗岩被志留纪-泥盆纪叶状变花岗片麻岩(此处称为Pocoshock Creek片麻岩)的地图尺度隔层分隔开。石英白云母长英片岩捕体的激光烧蚀-电感耦合等离子体质谱数据显示其峰值年龄模式约为529 Ma,我们将其解释为最大沉积年龄。从叶状变花岗片麻岩和块状等花岗岩体中继承的锆石从约631 Ma到约376 Ma不等,但大部分为寒武系锆石。新元古代-寒武纪石英-白云母长英片岩和角闪岩、志留纪-泥盆纪Pocoshock Creek片麻岩和宾夕法尼亚-二叠纪花岗岩组成了一个断层包围的地体,本文将其称为Dinwiddie地体。火成岩中继承的锆石岩心年龄和有限的碎屑锆石年代学表明该地体具有近冈瓦南的亲和性。片理变质类片麻岩的锆石颗粒愈合裂缝U/Pb年龄表明片麻岩在378 ~ 376 Ma左右发生过低程度的变形,而许多颗粒的边缘约320 ~ 280 Ma记录了晚古生代花岗岩的侵入。丁威迪地体的温度-时间-变形历史与相邻的古奇兰地体和罗阿诺克急流地体不同。造山带尺度的右向挤压作用可能使丁威迪地体在阿勒哈尼亚造山运动期间南移,在此期间,丁威迪地体被宾夕法尼亚-二叠纪花岗岩侵入。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Redefinition of the Petersburg batholith and implications for crustal inheritance in the Dinwiddie terrane, Virginia, USA
Field relations as well as geochemical and petrologic studies of meta-igneous rocks assigned to the Pennsylvanian–Permian Petersburg batholith identify at least two distinct rock types: foliated metagranitoid gneiss and massive to porphyritic granite. Foliated metagranitoid gneiss of mostly granodioritic composition is geochemically distinct from associated massive and porphyritic granitic rocks. These gneissic rocks yield radiometric ages from ca. 425 Ma to ca. 403 Ma and document that many of the rocks assigned to the late Paleozoic Petersburg batholith are 100 m.y. older than the youngest portions of the composite batholith and are part of an earlier infrastructural terrane. Two samples of massive equigranular granite southwest of Petersburg, Virginia, yield ages of ca. 321 Ma and ca. 317 Ma, which are 15–20 m.y. older than ca. 300 Ma ages for porphyritic granite, massive granite, and monzodiorite near Richmond, Virginia. Geologic mapping shows that the Early Pennsylvanian granite southwest of Petersburg is separated from Late Pennsylvanian to early Permian granite near Richmond by a map-scale septum of Silurian–Devonian foliated metagranitoid gneiss, referred to herein as the informal Pocoshock Creek gneiss. Laser ablation–inductively coupled plasma–mass spectrometry data from one sample of a quartz-muscovite felsic schist xenolith show a peak age mode of ca. 529 Ma that we interpret to be the maximum depositional age. Inherited zircons from foliated metagranitoid gneiss and massive equigranular granite range from ca. 631 Ma to ca. 376 Ma, but many are Cambrian. Neoproterozoic–Cambrian quartz-muscovite felsic schist and amphibolite, Silurian–Devonian Pocoshock Creek gneiss, and Pennsylvanian–Permian granite comprise a fault-bounded terrane referred to herein as the Dinwiddie terrane. Ages of inherited cores in zircon from igneous rocks and limited detrital zircon geochronology suggest the terrane is of peri-Gondwanan affinity. U/Pb ages of healed fractures in zircon grains from foliated metagranitoid gneiss indicate low-grade deformation of the gneiss at ca. 378–376 Ma, while ca. 320–280 Ma rims on many grains record intrusion of late Paleozoic granite. The temperature-time-deformation history of the Dinwiddie terrane is distinct from the adjacent Goochland and Roanoke Rapids terranes. Orogen-scale dextral transpression likely translated the Dinwiddie terrane southward during the Alleghanian orogeny, at which time they were intruded by Pennsylvanian to Permian granite.
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来源期刊
Geosphere
Geosphere 地学-地球科学综合
CiteScore
4.40
自引率
12.00%
发文量
71
审稿时长
6-12 weeks
期刊介绍: Geosphere is GSA''s ambitious, online-only publication that addresses the growing need for timely publication of research results, data, software, and educational developments in ways that cannot be addressed by traditional formats. The journal''s rigorously peer-reviewed, high-quality research papers target an international audience in all geoscience fields. Its innovative format encourages extensive use of color, animations, interactivity, and oversize figures (maps, cross sections, etc.), and provides easy access to resources such as GIS databases, data archives, and modeling results. Geosphere''s broad scope and variety of contributions is a refreshing addition to traditional journals.
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