Geochemical modeling to aid experimental design for multiple isotope tracer studies of coupled dissolution and precipitation reaction kinetics

IF 1.4 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS Acta Geochimica Pub Date : 2023-12-21 DOI:10.1007/s11631-023-00654-2
Mingkun Chen, Peng Lu, Yongchen Song, Chen Zhu
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Abstract

It is a challenge to make thorough but efficient experimental designs for the coupled mineral dissolution and precipitation studies in a multi-mineral system, because it is difficult to speculate the best experimental duration, optimal sampling schedule, effects of different experimental conditions, and how to maximize the experimental outputs prior to the actual experiments. Geochemical modeling is an efficient and effective tool to assist the experimental design by virtually running all scenarios of interest for the studied system and predicting the experimental outcomes. Here we demonstrated an example of geochemical modeling assisted experimental design of coupled labradorite dissolution and calcite and clayey mineral precipitation using multiple isotope tracers. In this study, labradorite (plagioclase) was chosen as the reactant because it is both a major component and one of the most reactive minerals in basalt. Following our isotope doping studies of single minerals in the last ten years, initial solutions in the simulations were doped with multiple isotopes (e.g., Ca and Si). Geochemical modeling results show that the use of isotope tracers gives us orders of magnitude more sensitivity than the conventional method based on concentrations and allows us to decouple dissolution and precipitation reactions at near-equilibrium condition. The simulations suggest that the precise unidirectional dissolution rates can inform us which rate laws plagioclase dissolution has followed. Calcite precipitation occurred at near-equilibrium and the multiple isotope tracer experiments would provide near-equilibrium precipitation rates, which was a challenge for the conventional concentration-based experiments. In addition, whether the precipitation of clayey phases is the rate-limiting step in some multi-mineral systems will be revealed. Overall, the modeling results of multi-mineral reaction kinetics will improve the understanding of the coupled dissolution–precipitation in the multi-mineral systems and the quality of geochemical modeling prediction of CO2 removal and storage efficacy in the basalt systems.

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建立地球化学模型,为溶解和沉淀耦合反应动力学的多同位素示踪研究的实验设计提供帮助
在多矿物系统中进行矿物溶解和沉淀耦合研究时,如何进行周密而有效的实验设计是一项挑战,因为在实际实验之前很难推测最佳实验时间、最佳取样时间表、不同实验条件的影响以及如何使实验产出最大化。地球化学建模是协助实验设计的高效工具,它可以虚拟运行所研究系统的所有相关方案,并预测实验结果。在此,我们展示了一个利用多种同位素示踪剂对拉长石溶解和方解石及粘土矿物沉淀进行耦合实验设计的地球化学建模辅助实例。在这项研究中,我们选择拉长石(斜长石)作为反应物,因为它既是玄武岩的主要成分,也是反应性最强的矿物之一。根据我们过去十年对单一矿物的同位素掺杂研究,模拟中的初始溶液掺杂了多种同位素(如钙和硅)。地球化学建模结果表明,与传统的基于浓度的方法相比,同位素示踪剂的使用使我们的灵敏度提高了几个数量级,并使我们能够在近平衡条件下解耦溶解和沉淀反应。模拟结果表明,精确的单向溶解速率可以告诉我们斜长石溶解所遵循的速率规律。方解石沉淀发生在近平衡状态下,多同位素示踪实验可提供近平衡沉淀速率,这对传统的基于浓度的实验是一个挑战。此外,粘土相的沉淀是否是某些多矿物系统中的限速步骤也将得到揭示。总之,多矿物反应动力学建模结果将加深对多矿物系统中溶解-沉淀耦合过程的理解,并提高玄武岩系统中二氧化碳去除和封存效果的地球化学建模预测质量。
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来源期刊
Acta Geochimica
Acta Geochimica GEOCHEMISTRY & GEOPHYSICS-
CiteScore
2.80
自引率
6.20%
发文量
1134
期刊介绍: Acta Geochimica serves as the international forum for essential research on geochemistry, the science that uses the tools and principles of chemistry to explain the mechanisms behind major geological systems such as the Earth‘s crust, its oceans and the entire Solar System, as well as a number of processes including mantle convection, the formation of planets and the origins of granite and basalt. The journal focuses on, but is not limited to the following aspects: • Cosmochemistry • Mantle Geochemistry • Ore-deposit Geochemistry • Organic Geochemistry • Environmental Geochemistry • Computational Geochemistry • Isotope Geochemistry • NanoGeochemistry All research articles published in this journal have undergone rigorous peer review. In addition to original research articles, Acta Geochimica publishes reviews and short communications, aiming to rapidly disseminate the research results of timely interest, and comprehensive reviews of emerging topics in all the areas of geochemistry.
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