Estimating Biogeochemical Rates Using a Computationally Efficient Lagrangian Approach

IF 2.3 3区 环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES Estuaries and Coasts Pub Date : 2024-06-24 DOI:10.1007/s12237-024-01381-4
Edward Gross, Rusty Holleman, Wim Kimmerer, Tamara Kraus, Brian Bergamaschi, Scott Burdick-Yahya, David Senn
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Abstract

Nutrient concentrations in many estuaries have increased over the past century due to increases in wastewater discharge and increased agricultural intensity, contributing to multiple environmental problems. Numerous biogeochemical and physical processes in estuaries influence nutrient concentrations during transport, resulting in complex spatial and temporal variability and challenges identifying predominant processes and their rates. Mechanistic models which require these rates to quantify biogeochemical processes become complex and difficult to calibrate as the number of processes and parameters grows, owing to the high dimensionality of the parameter space and the computational cost of simultaneously modeling the transport and transformations of constituents. We developed a modeling approach that decouples transport from transformations, enabling fast, data-driven exploration of the parameter space. The approach extracted information including water age, cumulative exposure to specific habitats, and mean water depth exposure from a hydrodynamic model. Using this information, a biogeochemical model was implemented to predict ammonium and nitrate concentrations in a Lagrangian frame. The model performed each simulation in milliseconds on a laptop computer, allowing the fitting of rate parameters for key transformations by optimization. The optimization used fixed station nitrate observations and the model was then validated against high-resolution mapping observations of ammonium and nitrate. The results suggest that the observed spatial and temporal variation can be largely represented with five transformation processes and their associated rates. Dissolved inorganic nitrogen (DIN) losses occurred only in shallow vegetated areas in the model, highlighting that biogeochemical processes in these areas should be included in DIN models.

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利用计算效率高的拉格朗日方法估算生物地球化学速率
在过去的一个世纪里,由于废水排放的增加和农业强度的提高,许多河口的营养物浓度都在增加,从而引发了多种环境问题。河口的众多生物地球化学和物理过程会在迁移过程中影响营养物浓度,从而导致复杂的时空变异性,并给确定主要过程及其速率带来挑战。随着过程和参数数量的增加,需要这些速率来量化生物地球化学过程的机理模型变得复杂且难以校准,原因在于参数空间的高维度以及同时模拟成分迁移和转化的计算成本。我们开发了一种建模方法,将迁移与转化分离开来,从而能够快速、数据驱动地探索参数空间。该方法从流体力学模型中提取的信息包括水龄、特定栖息地的累积暴露量和平均水深暴露量。利用这些信息,实施了一个生物地球化学模型,以预测拉格朗日框架中的铵和硝酸盐浓度。该模型在笔记本电脑上以毫秒为单位进行每次模拟,并通过优化拟合关键转化的速率参数。优化使用了固定观测站的硝酸盐观测数据,然后根据铵和硝酸盐的高分辨率绘图观测数据对模型进行了验证。结果表明,观测到的空间和时间变化在很大程度上可以用五个转化过程及其相关速率来表示。在该模型中,溶解无机氮(DIN)的损失仅发生在浅植被区,这表明这些区域的生物地球化学过程应被纳入 DIN 模型。
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来源期刊
Estuaries and Coasts
Estuaries and Coasts 环境科学-海洋与淡水生物学
CiteScore
5.60
自引率
11.10%
发文量
107
审稿时长
12-24 weeks
期刊介绍: Estuaries and Coasts is the journal of the Coastal and Estuarine Research Federation (CERF). Begun in 1977 as Chesapeake Science, the journal has gradually expanded its scope and circulation. Today, the journal publishes scholarly manuscripts on estuarine and near coastal ecosystems at the interface between the land and the sea where there are tidal fluctuations or sea water is diluted by fresh water. The interface is broadly defined to include estuaries and nearshore coastal waters including lagoons, wetlands, tidal fresh water, shores and beaches, but not the continental shelf. The journal covers research on physical, chemical, geological or biological processes, as well as applications to management of estuaries and coasts. The journal publishes original research findings, reviews and perspectives, techniques, comments, and management applications. Estuaries and Coasts will consider properly carried out studies that present inconclusive findings or document a failed replication of previously published work. Submissions that are primarily descriptive, strongly place-based, or only report on development of models or new methods without detailing their applications fall outside the scope of the journal.
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