Hematite reconstruction of Late Triassic hydroclimate over the Colorado Plateau

C. Lepre, P. Olsen
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引用次数: 12

Abstract

Significance Hematite provides much of the color for the classic Triassic–Jurassic “red beds” of North America and elsewhere. Measuring the spectrum of visible light reflected and absorbed by the red beds, we demonstrate that the hematite concentrations faithfully track 14.5 million years of Late Triassic monsoonal rainfall over the Colorado Plateau of Arizona and use this information to assess interrelationships between environmental perturbations, climate, and the evolution of terrestrial vertebrates. The research challenges conventional ideas that the hematite has limited use for interpreting the ancient past because it is a product of natural chemical alterations that occurred long after the beds were initially deposited. Hematite is the most abundant surficial iron oxide on Earth resulting from near-surface processes that make it important for addressing numerous geologic problems. While red beds have proved to be excellent paleomagnetic recorders, the early diagenetic origin of hematite in these units is often questioned. Here, we validate pigmentary hematite (“pigmentite”) as a proxy indicator for the Late Triassic environment and its penecontemporaneous origin by analyzing spectrophotometric measurements of a 14.5-My–long red bed sequence in scientific drill core CPCP-PFNP13-1A of the Chinle Formation, Arizona. Pigmentite concentrations in the red beds track the evolving pattern of the Late Triassic monsoon and indicate a long-term rise in aridity beginning at ∼215 Ma followed by increased oscillatory climate change at ∼213 Ma. These monsoonal changes are attributed to the northward drift of the Colorado Plateau as part of Laurentia into the arid subtropics during a time of fluctuating CO2. Our results refine the record of the Late Triassic monsoon and indicate significant changes in rainfall proximal to the Adamanian–Revueltian biotic transition that thus may have contributed to apparent faunal and floral events at 216 to 213 Ma.
科罗拉多高原晚三叠世水文气候的赤铁矿重建
意义赤铁矿为北美和其他地区的经典三叠纪-侏罗纪“红层”提供了大量的颜色。通过测量红层反射和吸收的可见光光谱,我们证明赤铁矿浓度忠实地追踪了亚利桑那州科罗拉多高原上1450万年的晚三叠世季风降雨,并利用这些信息来评估环境扰动、气候和陆源脊椎动物进化之间的相互关系。这项研究挑战了传统观点,即赤铁矿在解释古代历史方面的作用有限,因为它是在地层最初沉积很久之后发生的自然化学变化的产物。赤铁矿是地球上最丰富的表面氧化铁,是近地表过程的产物,对解决许多地质问题至关重要。虽然红层已被证明是优秀的古地磁记录者,但这些单元中赤铁矿的早期成岩成因经常受到质疑。本文通过对亚利桑那州Chinle组科学岩心CPCP-PFNP13-1A中14.5 m长的红层序列的分光光度测量,验证了色素赤铁矿(“色素赤铁矿”)作为晚三叠世环境及其准同生成因的替代指标。红层中的色素岩浓度跟踪了晚三叠世季风的演变模式,表明从~ 215 Ma开始干旱的长期上升,随后在~ 213 Ma振荡性气候变化加剧。这些季风变化归因于在二氧化碳波动期间,科罗拉多高原作为劳伦西亚的一部分向北漂移到干旱的亚热带。我们的研究结果完善了晚三叠世季风的记录,并表明在adamanian - revuelian生物过渡时期附近的降雨量发生了重大变化,因此可能对216至213 Ma的明显动物和植物事件做出了贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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