A Simple Approach to Modeling Light Attenuation in the Sacramento–San Joaquin Delta Using Commonly Available Data

Q3 Agricultural and Biological Sciences
Emily T. Richardson, Keith Bouma-Gregson, Katy O’Donnell, Brian Bergamaschi
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引用次数: 0

Abstract

The diffuse attenuation coefficient of photosynthetically active radiation (KdPAR) is commonly used to predict light attenuation in aquatic productivity models, but obtaining measurements of PAR to compute KdPAR is difficult. In situ calculations of KdPAR require multiple measurements of PAR through the water column, and these measurements are infeasible for real-time recording. Instead, predictive models using surface-water measurements may be used. Traditional KdPAR models are based on open-ocean habitats and rely on chlorophyll—as a proxy measurement for phytoplankton abundance—as the main predictive parameter. However, elevated suspended sediments and dissolved organic materials may also affect KdPAR values of inland water bodies and estuaries. In this study, we leverage KdPAR calculations derived from in situ light measurements collected along with surface-water-quality parameters across the Sacramento-San Joaquin River Delta in California, USA (the Delta). Sampling occurred between January of 2013 and May of 2014. We also explored regional and seasonal effects, but these did not clearly affect the model. Ultimately, the best-performing model included surface-level turbidity only (R2 = 0.91). The simplicity of the model facilitates use of KdPAR estimates for a variety of purposes throughout the Delta, including euphotic depth calculations, and as inputs to primary-productivity and habitat-suitability models. We demonstrate the model’s usability with two open-sources data sets (one spatially dense, and one temporally dense), and estimate KdPAR, euphotic depth, and primary productivity within the Delta. We provide calculations for each estimation, allowing users to easily adopt these models and apply them to their own data or with open-sourced data, which are abundant.
利用常见数据模拟萨克拉门托-圣华金三角洲光衰减的简单方法
光合有效辐射的漫射衰减系数(KdPAR)通常用于预测水生生产力模型中的光衰减,但要获得 PAR 的测量值来计算 KdPAR 却很困难。原位计算 KdPAR 需要多次测量贯穿水体的 PAR,而这些测量无法实时记录。取而代之的是使用表层水测量数据的预测模型。传统的 KdPAR 模型以开阔洋生境为基础,以叶绿素(浮游植物丰度的替代测量值)为主要预测参数。然而,悬浮沉积物和溶解有机物的增加也会影响内陆水体和河口的 KdPAR 值。在本研究中,我们利用在美国加利福尼亚州萨克拉门托-圣华金河三角洲(三角洲)采集的原位光照测量数据和地表水质参数得出的 KdPAR 计算结果。采样时间为 2013 年 1 月至 2014 年 5 月。我们还探讨了区域和季节效应,但这些效应并未对模型产生明显影响。最终,表现最佳的模型仅包括地表浊度(R2 = 0.91)。该模型简单易用,便于将 KdPAR 估算值用于整个三角洲的各种用途,包括计算透光深度,以及作为初级生产力和生境适宜性模型的输入。我们用两个开放源数据集(一个空间密集,一个时间密集)演示了该模型的可用性,并估算了三角洲内的 KdPAR、透光深度和初级生产力。我们提供了每次估算的计算结果,使用户可以轻松采用这些模型,并将其应用于自己的数据或大量开源数据。
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
San Francisco Estuary and Watershed Science
San Francisco Estuary and Watershed Science Environmental Science-Water Science and Technology
CiteScore
2.90
自引率
0.00%
发文量
24
审稿时长
24 weeks
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