Dispersal of optimal foragers in a patchy environment: Simulations with a mathematical model and tests of predictions in field experiments

IF 2.6 3区环境科学与生态学 Q2 ECOLOGY

Ecological Modelling Pub Date : 2024-09-23 DOI:10.1016/j.ecolmodel.2024.110887

Xavier Fauvergue , Keith R. Hopper

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引用次数: 0

Abstract

To predict the effect of density on the dispersal of foraging parasitoids, we developed a spatially explicit individual-based model in which parasitoids move among host patches at random but use an optimal decision-rule about when to leave these patches. We used a simple decision rule where an individual forager exploits a patch as long as the instantaneous attack rate is higher than the average attack rate it has experienced in the environment. Such a rule implies that foragers compute and remember attack rates as they forage. Simulations with different combinations of patch distribution, host density, mutual interference, and parasitoid density predicted that dispersal distance should increase with parasitoid density. To test this prediction, we used data from two field experiments in which we released either few or many adults of the aphid parasitoid Aphelinus asychis in replicated sites, and subsequently assessed dispersal from the spatial distribution of parasitoid offspring. In the first experiment, we did not to detect a relation between the number released and dispersal distance, but in the second experiment, dispersal distance increased with initial density, as predicted by our model. We propose two hypotheses to explain the discrepancy between the experiments. Different levels of environmental variability among experiments, resulting from differences in experimental designs, could cause differences in statistical conclusions. However, there could be a threshold density below which dispersal is not density-dependent, and this threshold may have been exceeded in the second experiment where large releases involved many more individuals than in the first experiment. In any case, our approach linked individual behavior and spatial distribution, and our results show that the insect distributions in the field can be predicted, qualitatively, from theory about individual behavior.

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斑块环境中最佳觅食者的散布：数学模型模拟和实地实验预测检验

为了预测密度对觅食寄生虫扩散的影响，我们建立了一个基于个体的空间显式模型，在该模型中，寄生虫在寄主斑块间随机移动，但在何时离开这些斑块上使用最优决策规则。我们使用了一个简单的决策规则，即只要瞬时攻击率高于环境中的平均攻击率，觅食者个体就会利用该斑块。这种规则意味着觅食者在觅食过程中会计算和记忆攻击率。通过对斑块分布、寄主密度、相互干扰和寄生虫密度的不同组合进行模拟，我们预测传播距离会随着寄生虫密度的增加而增加。为了验证这一预测，我们使用了两个野外实验的数据。在这两个实验中，我们在重复的地点释放了少量或大量的蚜虫寄生虫Aphelinus asychis成虫，随后根据寄生虫后代的空间分布评估了扩散情况。在第一个实验中，我们没有检测到释放数量与扩散距离之间的关系，但在第二个实验中，扩散距离随着初始密度的增加而增加，正如我们的模型所预测的那样。我们提出了两个假设来解释实验之间的差异。由于实验设计的不同，各实验之间的环境变异程度不同，这可能会导致统计结论的差异。然而，可能存在一个阈值密度，低于该阈值密度，扩散就不依赖于密度，而在第二次实验中，大量释放的个体数量比第一次实验多得多，可能已经超过了这个阈值。无论如何，我们的方法将个体行为与空间分布联系起来，我们的结果表明，根据个体行为的理论，可以定性地预测昆虫在野外的分布。

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

Ecological Modelling 环境科学-生态学

CiteScore

5.60

自引率

6.50%

发文量

259

审稿时长

69 days

期刊介绍： The journal is concerned with the use of mathematical models and systems analysis for the description of ecological processes and for the sustainable management of resources. Human activity and well-being are dependent on and integrated with the functioning of ecosystems and the services they provide. We aim to understand these basic ecosystem functions using mathematical and conceptual modelling, systems analysis, thermodynamics, computer simulations, and ecological theory. This leads to a preference for process-based models embedded in theory with explicit causative agents as opposed to strictly statistical or correlative descriptions. These modelling methods can be applied to a wide spectrum of issues ranging from basic ecology to human ecology to socio-ecological systems. The journal welcomes research articles, short communications, review articles, letters to the editor, book reviews, and other communications. The journal also supports the activities of the [International Society of Ecological Modelling (ISEM)](http://www.isemna.org/).