风化强度和锂同位素:反应迁移的观点

IF 1.9 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
M. Winnick, J. Druhan, K. Maher
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引用次数: 5

摘要

锂同位素已经成为探测全球风化对气候变化反应的有力工具。由于6Li在化学风化过程中优先与粘土矿物结合,因此δ7Li同位素比值可用于考察原生矿物溶解与粘土降水的平衡。这种平衡与化学和物理剥蚀的相对速率有关,因此,当化学和物理剥蚀相当时,溶解的δ7Li (δ7Lidiss)在中等风化强度下最高。然而,我们认为,目前的理论通过流体运动时间将δ7Li与风化机制联系起来,无法解释在快速侵蚀环境中观察到的低δ7Li和高Li浓度。在这项研究中,我们利用反应输运模型(CrunchFlow)将Li同位素纳入风化剖面模拟,重新研究了δ7Li、Li浓度和风化状态之间的关系,该模型包括风化层的平流通量,以模拟响应隆升的可变侵蚀速率。在这些模拟中,分馏是通过粘土沉淀过程中的动力学分馏因子来实现的,这使得模型中溶解和悬浮载荷的δ7Li随原生矿物和次生矿物中Li/Al比值的变化而变化。当模型在一定的入渗和侵蚀速率范围内运行时,模拟再现了观测到的δ7Lidiss和悬浮载荷δ7Li的全球模式,这些模式作为风化强度的函数,主要受风化基岩中的水移动时间和矿物停留时间的控制。然而,我们发现在低风化强度下减少的水行时间与高Li浓度的观测结果不一致。作为一种替代方案,我们证明了在低风化强度下,绿泥石等可溶性富锂矿物的快速风化可以解决数据和理论之间的明显差异。我们还认为观测到的模式与低风化强度下的地热锂源一致。这项工作为未来研究全球河流δ7Lidiss的潜在机制提供了指导基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Weathering intensity and lithium isotopes: A reactive transport perspective
Lithium isotopes have emerged as a powerful tool to probe the response of global weathering to changes in climate. Due to the preferential incorporation of 6Li into clay minerals during chemical weathering, the isotope ratio δ7Li may be used to interrogate the balance of primary mineral dissolution and clay precipitation. This balance has been linked to relative rates of chemical and physical denudation, such that dissolved δ7Li (δ7Lidiss) is highest at moderate weathering intensities when chemical and physical denudation are comparable. However, we argue that current theory linking δ7Li to weathering regimes through fluid travel times are unable to explain observations of low δ7Li and high Li concentrations in rapidly eroding settings. In this study, we re-examine the relationships between δ7Li, Li concentration, and weathering regime by incorporating Li isotopes into simulations of weathering profiles using a reactive transport model (CrunchFlow) that includes advective fluxes of regolith to simulate variable erosion rates in response to uplift. In these simulations, fractionation is implemented through a kinetic fractionation factor during clay precipitation, which allows the δ7Li of dissolved and suspended loads in the model to vary as a function of Li/Al ratios in primary and secondary minerals. When the model is run over a range of infiltration and erosion rates, simulations reproduce observed global patterns of δ7Lidiss and suspended load δ7Li as a function of weathering intensity, controlled primarily by water travel times and mineral residence times in weathered bedrock. We find that reduced water travel times at low weathering intensity, however, are inconsistent with observations of high Li concentrations. As an alternative, we demonstrate how the rapid weathering of soluble, Li-rich minerals such as chlorite under low weathering intensities may resolve this apparent discrepancy between data and theory. We also suggest that observed patterns are consistent with geothermal Li sources under low weathering intensities. This work offers a foundation guiding future studies in testing potential mechanisms underlying global riverine δ7Lidiss.
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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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