弗兰格里亚玻璃斜坡:美国阿拉斯加麦卡锡组晚三叠世至早侏罗世外斜坡环境

IF 2 4区 地球科学 Q1 GEOLOGY
Y. Veenma, Kayla Mccabe, A. Caruthers, M. Aberhan, M. Golding, S. Marroquín, J. Owens, T. Them, Benjamin C Gill, J. Trabucho Alexandre
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引用次数: 0

摘要

在泛大陆边缘沉积的浅海相序列中,特别是在其特提斯边缘沉积的三叠纪-侏罗纪边界段的海相记录已经得到了广泛的研究。由于中大西洋岩浆省(CAMP)的火成岩活动(包括生物钙化危机和三叠纪末大灭绝)的影响,其中一些序列显示出从富含碳酸盐地层到缺乏碳酸盐地层的相变化。目前,三叠纪-侏罗纪边界区间钙质沉积减少和生物硅质沉积增加的证据仅限于泛大陆的大陆边缘,没有来自最大的海洋盆地——开放的泛地中海海洋的数据。在这里,我们对McCarthy组(石洞溪,阿拉斯加中南部)进行了相分析,该组代表了Wrangellia的Norian至Hettangian深水沉积,然后是热带Panthalassan洋东部的一个孤立的海洋高原。本研究中定义的相组合代表了生物沉积物从浅水到外斜坡的组成和速率的变化。最上层的诺里纪到最下层的河塘纪代表了一个以远洋沉积为主的~ 8.9 myr的沉积物饥饿期。雷蒂安时期的沉积速率与河塘岸最下层相似的沉积速率相比异常低。因此,我们推断雷蒂亚盆地可能存在几次短暂中断,这是生物沉积物输入减少的结果。在鹤唐期,McCarthy组上下段的分界标志着浅水骨架颗粒的组成由钙质向生物硅质转变。这一变化也与沉积速率的数量级增加相吻合,代表了三叠纪-侏罗纪界线后约400 kyr从硅质碳酸盐斜坡到玻璃斜坡的转变。河塘间的几组大尺度低角度交叉层积被解释为一种由底流引起的沉积物漂移(流质沉积)。河塘间上段致密岩(浊积岩)和轮廓岩的生物硅质组成反映了晚三叠世浅水碳酸盐岩环境中早侏罗世硅质海绵的优势。这种优势是由三叠纪末的大灭绝和碳酸盐工厂的崩溃,以及由于CAMP玄武岩的风化作用,流入海洋的硅通量增加所带来的。弗兰格里亚玻璃斜坡的存在支持了一个假设,即全球海洋二氧化硅浓度的增加促进了三叠纪到侏罗纪过渡时期斜坡上广泛的生物硅沉积。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The glass ramp of Wrangellia: Late Triassic to Early Jurassic outer ramp environments of the McCarthy Formation, Alaska, U.S.A.
The marine record of the Triassic–Jurassic boundary interval has been studied extensively in shallow-marine successions deposited along the margins of Pangea, particularly its Tethyan margins. Several of these successions show a facies change from carbonate-rich to carbonate-poor strata attributed to the consequences of igneous activity in the Central Atlantic Magmatic Province (CAMP), which included a biocalcification crisis and the end-Triassic mass extinction. Evidence for a decline in calcareous and an increase in biosiliceous sedimentation across the Triassic–Jurassic boundary interval is currently limited to the continental margins of Pangea with no data from the open Panthalassan Ocean, the largest ocean basin. Here, we present a facies analysis of the McCarthy Formation (Grotto Creek, southcentral Alaska), which represents Norian to Hettangian deepwater sedimentation on Wrangellia, then an isolated oceanic plateau in the tropical eastern Panthalassan Ocean. The facies associations defined in this study represent changes in the composition and rate of biogenic sediment shedding from shallow water to the outer ramp. The uppermost Norian to lowermost Hettangian represent an ∼ 8.9-Myr-long interval of sediment starvation dominated by pelagic sedimentation. Sedimentation rates during the Rhaetian were anomalously low compared to sedimentation rates in a similar lowermost Hettangian facies. Thus, we infer the likelihood of several short hiatuses in the Rhaetian, a result of reduced input of biogenic sediment. In the Hettangian, the boundary between the lower and upper members of the McCarthy Formation represents a change in the composition of shallow-water skeletal grains shed to the outer ramp from calcareous to biosiliceous. This change also coincides with an order-of-magnitude increase in sedimentation rates and represents the transition from a siliceous carbonate-ramp to a glass ramp ∼ 400 kyr after the Triassic–Jurassic boundary. Sets of large-scale low-angle cross-stratification in the Hettangian are interpreted as a bottom current–induced sediment drift (contouritic sedimentation). The biosiliceous composition of densites (turbidites) and contourites in the Hettangian upper member reflects the Early Jurassic dominance of siliceous sponges over Late Triassic shallow-water carbonate environments. This dominance was brought about by the end-Triassic mass extinction and the collapse of the carbonate factory, as well as increased silica flux to the ocean as a response to the weathering of CAMP basalts. The presence of a glass ramp on Wrangellia supports the hypothesis that global increases in oceanic silica concentrations promoted widespread biosiliceous sedimentation on ramps across the Triassic to Jurassic transition.
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来源期刊
CiteScore
3.80
自引率
5.00%
发文量
50
审稿时长
3 months
期刊介绍: The journal is broad and international in scope and welcomes contributions that further the fundamental understanding of sedimentary processes, the origin of sedimentary deposits, the workings of sedimentary systems, and the records of earth history contained within sedimentary rocks.
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