奥陶系灰分地球化学与陆生植物的建立

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
John Parnell, Sorcha Foster
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引用次数: 19

摘要

陆地植物对陆地环境的殖民改变了行星表面及其生物群,使地球生物量的平衡从地下向地表转移。然而,古土壤(土壤)在陆地表面的形成与植物定植的关键阶段之间有很长的延迟。古土壤的记录,以及真菌和地衣对它们的殖民,可以追溯到前寒武纪。虽然这些早期土壤提供了潜在的基质,但作为风化过程的一部分,它们通常会浸出营养物质。相比之下,火山灰瀑布提供了一种地球化学上有利的基质,既营养丰富,又具有高保水性,使它们成为陆地植物的好宿主。在奥陶纪期间,异常广泛的火山弧系统产生了前所未有的熔岩和火山灰(凝灰岩)。最早的,中奥陶世,植物孢子的记录与这些广泛的火山沉积物相吻合,这表明可能存在遗传关系。火山灰构成了一个营养丰富、水分饱和的全球土壤环境,陆地植物不断进化的锚定系统可以最大限度地利用这种环境。植物孢子和共生固氮真菌对现代火山灰的快速和广泛接种表明,奥陶纪火山灰一定接受了大量最早孢子的负荷,它们的化学作用有利于植物的发育。特别是白蜡树中磷含量高,有利于植物生长。这可能使光合作用变得多样化和扩大,并改变了地球的表面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Ordovician ash geochemistry and the establishment of land plants

Ordovician ash geochemistry and the establishment of land plants

The colonization of the terrestrial environment by land plants transformed the planetary surface and its biota, and shifted the balance of Earth’s biomass from the subsurface towards the surface. However there was a long delay between the formation of palaeosols (soils) on the land surface and the key stage of plant colonization. The record of palaeosols, and their colonization by fungi and lichens extends well back into the Precambrian. While these early soils provided a potential substrate, they were generally leached of nutrients as part of the weathering process. In contrast, volcanic ash falls provide a geochemically favourable substrate that is both nutrient-rich and has high water retention, making them good hosts to land plants. An anomalously extensive system of volcanic arcs generated unprecedented volumes of lava and volcanic ash (tuff) during the Ordovician. The earliest, mid-Ordovician, records of plant spores coincide with these widespread volcanic deposits, suggesting the possibility of a genetic relationship. The ash constituted a global environment of nutrient-laden, water-saturated soil that could be exploited to maximum advantage by the evolving anchoring systems of land plants. The rapid and pervasive inoculation of modern volcanic ash by plant spores, and symbiotic nitrogen-fixing fungi, suggests that the Ordovician ash must have received a substantial load of the earliest spores and their chemistry favoured plant development. In particular, high phosphorus levels in ash were favourable to plant growth. This may have allowed photosynthesizers to diversify and enlarge, and transform the surface of the planet.

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来源期刊
Geochemical Transactions
Geochemical Transactions 地学-地球化学与地球物理
CiteScore
3.70
自引率
4.30%
发文量
2
审稿时长
>12 weeks
期刊介绍: Geochemical Transactions publishes high-quality research in all areas of chemistry as it relates to materials and processes occurring in terrestrial and extraterrestrial systems.
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