Use of process-based coupled ecological-hydrodynamic models to support lake water ecosystem service protection planning at the regional scale

IF 3.5 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Journal of contaminant hydrology Pub Date : 2024-11-26 DOI:10.1016/j.jconhyd.2024.104469

Andrea Fenocchi , Nicolò Pella , Diego Copetti , Fabio Buzzi , Daniele Magni , Nico Salmaso , Claudia Dresti

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Abstract

Protection plans of lake waters are based on ecological and/or chemical targets, often simplified in terms of total phosphorus (TP) concentrations, customarily the depth-averaged ones at spring mixing for temperate environments. These target lake TP concentrations are then commonly employed to determine target external loading through reverse use of Vollenweider-OECD-type steady-state empirical models. Such models are also adopted in their direct form to estimate lake TP concentrations following hypothetical external load reductions. However, such approaches suffer from extreme parameterisation and often give inaccurate results. Process-based coupled ecological-hydrodynamic models offer a much wider flexibility and produce an extensive set of information, solving many of the issues of Vollenweider-OECD-type models. However, their application has been up to now restricted to single lakes due to calibration effort and data availability burdens. To overcome these obstacles, in this study we developed a simplified application of the process-based coupled model QWET over 9 lakes in Northern Italy, making use of the ParSAC automatic calibration tool and feeding the models only with general data available from public monitoring. QWET models were calibrated over past observations, simulating nutrient reduction scenarios for the near-future decades. The advantages over traditionally employed models for lake water protection planning at the regional scale were hence identified through a practical application, determining the strengths and limits of the herein-adopted simplified process-based approach over lakes with different features. Obtained results were also analysed considering the specific case study.

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基于过程的耦合生态水动力模型在区域尺度上支持湖泊生态系统服务保护规划

湖泊水域的保护计划以生态和/或化学目标为基础，通常简化为总磷（TP）浓度，通常是温带环境春季混合时的深度平均浓度。这些目标湖泊总磷浓度通常通过反向使用vollenweider - oecd型稳态经验模型来确定目标外部负荷。这些模型也被直接用于估算假设外部负荷减少后的湖泊总磷浓度。然而，这种方法受到极端参数化的影响，常常给出不准确的结果。基于过程的耦合生态-水动力模型提供了更大的灵活性，并产生了广泛的信息集，解决了vollenweider - oecd型模型的许多问题。然而，由于校准工作和数据可用性负担，到目前为止，它们的应用仅限于单个湖泊。为了克服这些障碍，在这项研究中，我们开发了一个基于过程的耦合模型QWET在意大利北部9个湖泊的简化应用，利用ParSAC自动校准工具，并仅为模型提供来自公共监测的一般数据。QWET模型是根据过去的观测校准的，模拟了近未来几十年的营养减少情景。通过实际应用，确定了区域尺度上湖泊水体保护规划相对于传统模型的优势，确定了本文采用的基于简化过程的方法在不同湖泊特征上的优势和局限性。结合具体案例，对所得结果进行了分析。

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

Journal of contaminant hydrology 环境科学-地球科学综合

CiteScore

6.80

自引率

2.80%

发文量

129

审稿时长

68 days

期刊介绍： The Journal of Contaminant Hydrology is an international journal publishing scientific articles pertaining to the contamination of subsurface water resources. Emphasis is placed on investigations of the physical, chemical, and biological processes influencing the behavior and fate of organic and inorganic contaminants in the unsaturated (vadose) and saturated (groundwater) zones, as well as at groundwater-surface water interfaces. The ecological impacts of contaminants transported both from and to aquifers are of interest. Articles on contamination of surface water only, without a link to groundwater, are out of the scope. Broad latitude is allowed in identifying contaminants of interest, and include legacy and emerging pollutants, nutrients, nanoparticles, pathogenic microorganisms (e.g., bacteria, viruses, protozoa), microplastics, and various constituents associated with energy production (e.g., methane, carbon dioxide, hydrogen sulfide). The journal''s scope embraces a wide range of topics including: experimental investigations of contaminant sorption, diffusion, transformation, volatilization and transport in the surface and subsurface; characterization of soil and aquifer properties only as they influence contaminant behavior; development and testing of mathematical models of contaminant behaviour; innovative techniques for restoration of contaminated sites; development of new tools or techniques for monitoring the extent of soil and groundwater contamination; transformation of contaminants in the hyporheic zone; effects of contaminants traversing the hyporheic zone on surface water and groundwater ecosystems; subsurface carbon sequestration and/or turnover; and migration of fluids associated with energy production into groundwater.