Quantifying biotic and abiotic Si fluxes in the Critical Zone with Ge/Si ratios along a gradient of erosion rates

IF 1.9 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
P. Frings, Franziska Schubring, M. Oelze, F. von Blanckenburg
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引用次数: 6

Abstract

Silicon (Si) is an important nutrient for many plant and algae species, and the ultimate source of Si is silicate mineral weathering reactions. These topics have inspired the application of Si isotope geochemistry to quantifying Si cycling in the Critical Zone, though the interpretations are often equivocal. Because germanium (Ge) geochemistry is similar to that of Si, the Ge/Si ratio is considered a tracer that provides additional constraints on Si cycling. Here, we provide Ge/Si ratios for three sites that span a gradient of erosion rates and thus time that material spends in the weathering zone before being removed. We present Ge/Si ratios in bulk rock, soil and saprolite, clay-size fractions, plant biomass, and river water from the Central Swiss Alps, the southern Californian Sierra Nevada, and the highlands of Sri Lanka. Our data perform two functions. First, they provide insight into the Ge/Si system. In particular, we document the presence of a substantial pool of Ge in plant biomass that is not associated with phytoliths, suggesting that overall plants do not discriminate against Ge relative to Si during uptake. We also quantify the preferential incorporation of Ge into clay minerals. We show that Ge/Si ratios in secondary clays may be a better proxy for weathering intensity (the fraction of denudation achieved chemically) than the Ge/Si ratio of river solutes. Ge/Si ratios in secondary clay minerals also perform as well as or even better than silicon isotopes as weathering intensity proxies. Second, the Ge/Si data are used in conjunction with silicon isotope data to develop a catchment Si mass-balance model. It suggests that the export of secondary, fractionated solids (largely clays and plant material) becomes increasingly important at shorter regolith residence times: 80−24+15% of total solubilized Si in the rapidly eroding Alps site, vs. 32−20+22% in the slowly eroding Sri Lanka site. The results also suggest that plant material is a surprisingly large contributor to Si export from these catchments, likely equivalent to 25 to110 % of dissolved Si export.
利用Ge/Si比值沿侵蚀速率梯度量化临界带的生物和非生物硅通量
硅是许多植物和藻类的重要营养物质,硅的最终来源是硅酸盐矿物的风化反应。这些主题激发了硅同位素地球化学在量化临界区硅循环中的应用,尽管解释往往模棱两可。由于锗(Ge)地球化学与硅的地球化学相似,因此Ge/Si比率被认为是对硅循环提供额外约束的示踪剂。在这里,我们提供了三个地点的Ge/Si比率,这三个地点跨越了侵蚀率的梯度,因此材料在被移除之前在风化带中花费的时间。我们介绍了来自瑞士阿尔卑斯山脉中部、加利福尼亚内华达山脉南部和斯里兰卡高地的大块岩石、土壤和腐泥土、粘土粒级、植物生物量和河水中的Ge/Si比率。我们的数据具有两个功能。首先,它们提供了对Ge/Si系统的深入了解。特别是,我们记录了植物生物量中存在大量与植硅体无关的Ge,这表明在吸收过程中,整个植物相对于Si不会歧视Ge。我们还量化了Ge在粘土矿物中的优先掺入。我们表明,次生粘土中的Ge/Si比率可能比河流溶质中的Ge/Si比率更能代表风化强度(化学剥蚀的分数)。次生粘土矿物中的Ge/Si比率作为风化强度指标也与硅同位素一样好,甚至更好。其次,将Ge/Si数据与硅同位素数据相结合,建立了汇水硅质量平衡模型。这表明,在风化层停留时间较短的情况下,次级分馏固体(主要是粘土和植物材料)的出口变得越来越重要:在快速侵蚀的阿尔卑斯山地区,溶解硅占总溶解硅的80−24+15%,而在缓慢侵蚀的斯里兰卡地区,这一比例为32−20+22%。研究结果还表明,植物材料对这些集水区的硅出口贡献巨大,可能相当于溶解硅出口的25%至110%。
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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来源期刊
American Journal of Science
American Journal of Science 地学-地球科学综合
CiteScore
5.80
自引率
3.40%
发文量
17
审稿时长
>12 weeks
期刊介绍: The American Journal of Science (AJS), founded in 1818 by Benjamin Silliman, is the oldest scientific journal in the United States that has been published continuously. The Journal is devoted to geology and related sciences and publishes articles from around the world presenting results of major research from all earth sciences. Readers are primarily earth scientists in academia and government institutions.
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