Foundational uncertainties in terminal Ediacaran chronostratigraphy revealed by high-precision zircon U-Pb geochronology of the Nama Group, Namibia

IF 10 1区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY

Earth-Science Reviews Pub Date : 2025-05-23 DOI:10.1016/j.earscirev.2025.105169

Fred T. Bowyer , Fabio Messori , Rachel Wood , Ulf Linnemann , Esther Rojo-Perez , Mandy Zieger-Hofmann , Johannes Zieger , Junias Ndeunyema , Martin Shipanga , Bontle Mataboge , Dan Condon , Catherine V. Rose , Collen-Issia Uahengo , Sean P. Gaynor , Inigo A. Müller , Gerd Geyer , Torsten Vennemann , Joshua H.F.L. Davies , Maria Ovtcharova

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引用次数: 0

Abstract

The Nama Group of southern Namibia and northwestern South Africa hosts the best-dated mixed carbonate-siliciclastic foreland basin succession of the terminal Ediacaran [ca. 551 million years (Ma) ago to <538 Ma] and is key for resolving the chronology of early metazoan evolution. Numerous silicified volcanic tuff interbeds are present, but differing interpretations regarding the fidelity of their ages lead to different regional stratigraphic correlations, especially for the Urusis Formation of the Schwarzrand Subgroup. An expanded record of the Urusis Formation is found in the Swartpunt area of southern Namibia, which has yielded an important metazoan biota. But the succession in this area is preserved as a series of thrusts at the leading edge of the Gariep orogenic belt and zircon U-Pb data show systematic age repetition. We use regional stratigraphic and structural mapping, integrated with carbonate carbon isotope (δ¹³C_carb) chemostratigraphy and high-precision radioisotope U-Pb zircon geochronology from outcrop and recently acquired drill core to develop a temporally calibrated basin-wide depositional model. This integrated dataset either reflects complex zircon reworking, inheritance, or potential analytical biases (Scenario 1) or the presence of a Gariep-related cryptic décollement within the Spitskop Member that has resulted in stratigraphic repetition (Scenario 2). We investigate the evidence for and against both scenarios and consider their implications for stratigraphic and δ¹³C_carb correlations between the Swartpunt area and coeval exposures along the Orange River border with South Africa.

Given that these issues are in an area that hosts numerous silicified ash beds and extensive exposure, an inability to confidently discount either scenario highlights a level of compounding uncertainty in zircon U-Pb geochronology that must be considered when attempting to build global chronostratigraphic frameworks. Scenario 1 implies that some of the weighted mean ages and Bayesian eruption ages from the Swartpunt area may be >1 Myr older than the depositional age of their respective ash beds when assuming existing stratigraphic correlations. If this scenario is preferred, then a cautious approach would be to consider all weighted mean zircon U-Pb ages from ash beds to reflect maximum depositional ages. Both scenarios support deposition of the Huns Member >540 Ma in the Swartpunt area if the oldest weighted mean age reported here represents a near-depositional age, which has significant implications for the temporal calibration of important terminal Ediacaran ichnofossil assemblages and future cyclostratigraphic studies.

Stratigraphic correlations common to both scenarios allow us to temporally calibrate a basin evolution model for the Nama Group. Temporal trends in initial hafnium isotope (εHf) compositions of zircon grains from ash beds throughout the succession may support progressive crustal thickening associated with underplating of the Damara orogenic belt along the northern periphery of the Kalahari craton from ca. 547 Ma to ca. 538 Ma. The compilation of new and published zircon U-Pb ages may also imply that the locus of carbonate platform development migrated from north to south (present co-ordinates), tracking the migration of foredeep subsidence.

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纳米比亚Nama群高精度锆石U-Pb年代学揭示的埃迪卡拉末期年代地层基本不确定性

纳米比亚南部和南非西北部的Nama群拥有埃迪卡拉末期（约5.51亿年前至5.38亿年前）最具年代特征的碳酸盐-硅屑混合前陆盆地序列，是解决早期后生动物演化年代学问题的关键。存在大量硅化火山凝灰岩互层，但对其年龄的保真度的不同解释导致了不同的区域地层对比，特别是对于Schwarzrand亚群的Urusis组。在纳米比亚南部的Swartpunt地区发现了Urusis组的扩展记录，其中产生了一个重要的后生动物生物群。但该地区的演替被保存为加里普造山带前缘的一系列逆冲构造，锆石U-Pb数据显示出系统的年龄重复。通过区域地层和构造填图，结合碳酸盐岩碳同位素（δ13Ccarb）化学地层学和高精度放射性同位素U-Pb锆石年代学，从露头和最近获得的钻孔岩心中建立了一个时间校准的全盆地沉积模型。这个综合数据集要么反映了复杂的锆石改造、继承或潜在的分析偏差（场景1），要么反映了Spitskop成员中存在与gariep相关的隐性dsamicment，导致地层重复（场景2）。我们研究了支持和反对这两种情况的证据，并考虑了它们对Swartpunt地区与沿奥兰治河与南非边界的同时期暴露之间的地层和δ13Ccarb相关性的影响。考虑到这些问题所在的地区拥有大量的硅化灰层和广泛的暴露，无法自信地排除任何一种情况，这突显了锆石U-Pb地质年代学的复合不确定性，这在试图建立全球年代地层格架时必须考虑到。情景1表明，假设现有的地层相关性，Swartpunt地区的一些加权平均年龄和贝叶斯喷发年龄可能比各自火山灰床的沉积年龄早1 Myr。如果这种情况是优选的，那么一个谨慎的方法是考虑来自火山灰层的所有加权平均锆石U-Pb年龄，以反映最大沉积年龄。如果这里报告的最古老加权平均年龄代表了接近沉积年龄，那么这两种情景都支持斯瓦特庞特地区匈奴时期的沉积[gt；540 Ma]，这对重要的埃迪卡拉末期鱼化石组合的时间校准和未来的旋回地表学研究具有重要意义。这两种情况的共同地层对比使我们能够暂时校准纳玛群的盆地演化模型。在整个演替过程中，火山灰层中锆石颗粒的初始铪同位素（εHf）组成的时间变化趋势可能支持约547 ~ 538 Ma期间卡拉哈里克拉通北缘达马拉造山带底板相关的地壳渐进式增厚。新公布的锆石U-Pb年龄的编纂也可能暗示了碳酸盐岩台地发育的轨迹由北向南（现在坐标）迁移，跟踪了前深沉降的迁移。

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来源期刊

Earth-Science Reviews 地学-地球科学综合

CiteScore

21.70

自引率

5.80%

发文量

294

审稿时长

15.1 weeks

期刊介绍： Covering a much wider field than the usual specialist journals, Earth Science Reviews publishes review articles dealing with all aspects of Earth Sciences, and is an important vehicle for allowing readers to see their particular interest related to the Earth Sciences as a whole.