MUDDYING THE WATERS: MODELING THE EFFECTS OF EARLY LAND PLANTS IN PALEOZOIC ESTUARIES

IF 1.5 4区地球科学 Q2 GEOLOGY

Palaios Pub Date : 2021-06-03 DOI:10.2110/palo.2020.073

M. Brückner, W. McMahon, M. Kleinhans

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引用次数: 10

Abstract

Abstract: The Paleozoic evolution of vegetation transformed terrestrial landscapes, facilitating novel sedimentary processes and creating new habitats. This transformation left a permanent mark on the sedimentary record, perhaps most strikingly via an upsurge in preserved terrestrial mudrock. Whereas feedbacks between evolving vegetation and river structure have been widely studied, Paleozoic estuaries have so far received scant attention. Located at the interface between the land and sea, the co-adjustment of estuarine morphology and plant traits are fundamentally tied to a varied range of geochemical cycles, and determine how global silicate weathering patterns may have varied over time. Here we employ an eco-morphodynamic model with an in-built vegetation code to simulate estuarine morphology through five key stages in plant evolution. An abiotic model (early Precambrian?) saw mud deposition restricted to fortuitous instances of limited erosion along bar-flanks. Estuaries colonized by microbial mats (Precambrian onwards) facilitated mud accretion that sufficiently stabilized bar surfaces to promote extensive mudflat development. Small-stature, rootless vegetation (Silurian–Early Devonian) introduced novel above-ground baffling effects which led to notable mud accumulation in lower-energy environments. The incorporation of roots (Early Devonian) strengthened these trends, with root structures decreasing the mortality of the occupying plants. Once the full complement of modern vascular plant architectures had evolved (Middle Devonian), dense colonization promoted the formation of in-channel islands accompanied with system-wide mud accumulation. These simulations suggest estuaries underwent profound change during the Paleozoic, with the greening of the continents triggering processes and feedbacks which render all previous source-to-sink sediment pathways non-uniformitarian.

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搅浑水域：古生代河口早期陆地植物影响的建模

摘要：古生代植被的演化改变了陆地景观，促进了新的沉积过程，创造了新的栖息地。这种转变在沉积记录上留下了永久的印记，也许最引人注目的是保存下来的陆地泥岩的激增。尽管进化中的植被和河流结构之间的反馈已经被广泛研究，但古生代河口迄今为止很少受到关注。河口形态和植物特征的共同调整位于陆地和海洋之间的界面，从根本上与各种地球化学循环有关，并决定了全球硅酸盐风化模式如何随时间变化。在这里，我们使用一个生态形态动力学模型和一个内置的植被代码来模拟植物进化的五个关键阶段的河口形态。一个非生物模型（前寒武纪早期？）认为，泥浆沉积仅限于沿坝腹有限侵蚀的偶然情况。由微生物垫定殖的河口（前寒武纪以后）促进了淤泥的堆积，从而充分稳定了坝面，促进了广泛的泥滩开发。身材矮小、无根的植被（志留纪-早泥盆纪）引入了新的地上障碍效应，导致在低能量环境中显著的泥浆堆积。根的结合（早泥盆纪）加强了这些趋势，根结构降低了占据植物的死亡率。一旦现代维管束植物结构的完整组成已经进化（中泥盆纪），密集的定殖促进了海峡内岛屿的形成，并伴随着全系统的泥浆堆积。这些模拟表明，河口在古生代经历了深刻的变化，大陆的绿化引发了过程和反馈，使所有以前的源沉沉积物路径都不一致。

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来源期刊

Palaios 地学-地质学

CiteScore

2.80

自引率

12.50%

发文量

审稿时长

6 months

期刊介绍： PALAIOS is a monthly journal, founded in 1986, dedicated to emphasizing the impact of life on Earth''s history as recorded in the paleontological and sedimentological records. PALAIOS disseminates information to an international spectrum of geologists and biologists interested in a broad range of topics, including, but not limited to, biogeochemistry, ichnology, paleoclimatology, paleoecology, paleoceanography, sedimentology, stratigraphy, geomicrobiology, paleobiogeochemistry, and astrobiology. PALAIOS publishes original papers that emphasize using paleontology to answer important geological and biological questions that further our understanding of Earth history. Accordingly, manuscripts whose subject matter and conclusions have broader geologic implications are much more likely to be selected for publication. Given that the purpose of PALAIOS is to generate enthusiasm for paleontology among a broad spectrum of readers, the editors request the following: titles that generate immediate interest; abstracts that emphasize important conclusions; illustrations of professional caliber used in place of words; and lively, yet scholarly, text.