Devonian to Carboniferous continental-scale carbonate turnover in Western Laurentia (North America): upwelling or climate cooling?

IF 1.8 3区地球科学 Q1 GEOLOGY

Facies Pub Date : 2022-01-01 Epub Date: 2022-07-25 DOI:10.1007/s10347-022-00653-4

Makram Hedhli, Keith Dewing, Benoit Beauchamp, Stephen E Grasby, Rudi Meyer

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引用次数: 1

Abstract

The Devonian to Carboniferous (DC) transition coincided with a green-to-ice house climatic shift, anoxia, disappearance of lower latitude carbonate banks, and turnover from warm-to-cool water carbonate factories. In western Laurentia, the switch to carbonate factories dominated by cool-water biota was contemporaneous with a tectonically driven palaeogeographic change. To investigate this depositional shift and infer the relative impact of climate vs tectonics, a continental-scale sedimentological and geochemical study was conducted on twelve stratigraphic sections of DC strata from western Canada to southern Nevada (USA). The spatial-temporal distribution of microfacies records the turnover from [i] a Famennian lime mud-rich, shallow warm-water carbonate ramp with low sedimentation rates, mesotrophic conditions and tabular geometry to [ii] Tournaisian to Viséan lime mud-depleted and grainstone dominated cool-water carbonate ramp with anomalous high sedimentation rates, oligotrophic conditions and a pronounced slope. Positive excursions of δ ¹⁸O_carb (+ 2‰ V-PDB) and δ ¹³C_carb (+ 4‰ V-PDB) of Lower Mississippian carbonates likely correspond to the first cooling peak of the Carboniferous-Permian icehouse climate, following carbon withdrawal during black shale deposition during the late Famennian and early Tournaisian. However, late Tournaisian return of photozoan elements and their persistence throughout the Viséan suggests that warmer surface water existed, revealing a decoupling of the lower latitude ocean and the atmosphere. Shoaling of the thermocline was likely a result of cold-water upwelling along an open coast, as the Antler orogen no longer provided an oceanic obstruction to the west. This study shows that carbonate platforms are more susceptible to regional changes than global shifts.

Supplementary information: The online version contains supplementary material available at 10.1007/s10347-022-00653-4.

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西劳伦西亚(北美)泥盆纪至石炭纪大陆尺度碳酸盐转换:上升流还是气候冷却?

泥盆纪到石炭纪(DC)的过渡与绿色到冰屋的气候变化、缺氧、低纬度碳酸盐滩的消失以及温水碳酸盐工厂向冷水碳酸盐工厂的转变相吻合。在劳伦西亚西部，向以冷水生物群为主的碳酸盐工厂的转变与构造驱动的古地理变化是同步的。为了研究这种沉积转移，推断气候与构造的相对影响，对加拿大西部至美国内华达州南部的12个DC地层剖面进行了大陆尺度的沉积学和地球化学研究。微相的时空分布记录了从[i]法门系富灰泥、低沉积速率、中营养条件和板状结构的浅层温水碳酸盐岩斜坡到[ii]图尔奈系至visaiman期贫灰泥、颗粒岩为主、异常高沉积速率、少营养条件和明显斜坡的冰水碳酸盐岩斜坡的转换过程。下密西统碳酸盐岩δ 18Ocarb(+ 2‰V-PDB)和δ 13ocarb(+ 4‰V-PDB)的正偏移可能对应于石炭-二叠纪冰库气候的第一个冷却峰，这是在法门世晚期和图尔纳世早期黑色页岩沉积过程中的碳提取。然而，图尔奈晚期光生动物元素的回归以及它们在整个vissaman的持续存在表明，温暖的地表水存在，揭示了低纬度海洋和大气的脱钩。温跃层的浅滩化很可能是由于沿着开阔海岸的冷水上涌造成的，因为鹿角造山带不再为西部提供海洋障碍。研究表明，碳酸盐岩台地更容易受到区域变化的影响，而不是全球变化的影响。补充信息:在线版本包含补充资料，可在10.1007/s10347-022-00653-4获得。

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来源期刊

Facies 地学-地质学

CiteScore

3.70

自引率

5.60%

发文量

审稿时长

>12 weeks

期刊介绍： The journal is open to papers dealing with the interpretation of ancient and modern biotopes and carbonate depositional environments by means of facies analysis in its broadest sense. Once the central part of research in hydrocarbon exploration, facies analysis more and more integrates modern and ancient biogeological processes of a changing earth. Special emphasis is laid on paleobiology and -ecology, basin evolution, sedimentology including diagenesis and geochemistry, as well as studies emphasising the impact of life on earth history. The main part of the target group will be people in academia.