Linking NPZD and foodweb models of an estuarine lagoon ecosystem

A. Erturk, A. Razinkovas, P. Zemlys, R. Pilkaitytė, Z. Gasiūnaitė
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引用次数: 3

Abstract

Among aquatic ecosystems, estuarine lagoons are generally more complex than inland waters because of the combined effect of the land and the sea. These systems are under the influence of land through the rivers and have a restricted and temporally variable water exchange with the seas or the oceans. Estuarine lagoons are generally productive ecosystems which offer habitats for many species. Many coastal and estuarine lagoons are known to be important components of the natural capital providing opportunities for aquaculture. These ecosystems are difficult to analyze. Like most of the transitional waters, their trophic and ecological status cannot be defined easily because of their complexity. Most of them are usually under strong human influence or already modified heavily, which makes this task even more difficult. Nutrient phytoplankton zooplankton detritus (NPZD) models can help scientists to analyze the full picture of an aquatic system, together with physical, chemical and biological processes, to fill in the gaps of data between samplings and to forecast environmental changes and use this output for planning. Traditionally, these models have been developed and used by engineers extensively, usually with the aim of water resources and quality management. However, different needs may arise in ecological studies with different aims such as better understanding how an aquatic ecosystem works or analyze the interactions in an aquatic food web. In this case, different state variables may be needed than the conventional ones, which are used by more general water quality models that are available. In ecological studies, related to coastal lagoon ecosystems organism groups on the higher trophic levels can be of interest. In this study, an NPZD model and a trophic network model that contains organism groups on the higher trophic levels were linked using the ldquobottom-up controlrdquo approach. Such a linkage of models provides the possibility to use the advantages of both models; reproducing of the erratic behavior of nutrients and plankton as realistic as possible, while still taking the more complex organisms in the trophic network, which respond to external forcing in a larger time scale. The models developed in this study were applied to the Curonian Lagoon that is an important estuarine ecosystem for Lithuania.
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连接NPZD和河口泻湖生态系统的食物网模型
在水生生态系统中,由于陆地和海洋的共同作用,河口泻湖通常比内陆水域更为复杂。这些系统受陆地通过河流的影响,与海洋的水交换是有限的和暂时可变的。河口泻湖通常是多产的生态系统,为许多物种提供栖息地。众所周知,许多沿海和河口泻湖是为水产养殖提供机会的自然资本的重要组成部分。这些生态系统很难分析。与大多数过渡水域一样,由于其复杂性,其营养和生态状况不易确定。其中大多数通常受到强烈的人类影响或已经被大量修改,这使得这项任务更加困难。营养性浮游植物浮游动物碎屑(NPZD)模型可以帮助科学家分析水生系统的全貌,以及物理、化学和生物过程,填补采样之间的数据空白,预测环境变化,并将这一结果用于规划。传统上,这些模型被工程师广泛开发和使用,通常是为了水资源和质量管理。然而,不同目的的生态学研究可能会产生不同的需求,例如更好地了解水生生态系统如何工作或分析水生食物网中的相互作用。在这种情况下,可能需要不同的状态变量,而不是常规的状态变量,这些状态变量被更一般的水质模型所使用。在生态学研究中,与沿海泻湖生态系统有关的较高营养水平的生物群可能引起人们的兴趣。在本研究中,NPZD模型和包含更高营养水平生物群的营养网络模型使用ldquo自下而上控制方法进行关联。这种模型的联系提供了利用两种模型的优点的可能性;尽可能真实地再现营养物和浮游生物的不稳定行为,同时仍然采用营养网络中更复杂的生物,它们在更大的时间尺度上对外部强迫作出反应。本研究中开发的模型应用于库尔潟湖,这是立陶宛重要的河口生态系统。
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