超越平面：鱼群在3D中采用阶梯形式。

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-06-27 DOI:10.1038/s41598-025-06150-2

Hungtang Ko, Abigail Girma, Yangfan Zhang, Yu Pan, George Lauder, Radhika Nagpal

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引用次数: 0

摘要

鱼群的协调运动长期以来一直吸引着研究动物集体行为的研究人员。Weihs和Lighthill的经典文献表明，鱼群应该倾向于平面钻石地层，以提高水动力效率，这激发了从流体模拟到水翼实验的大量工作。然而，鱼群是否真的采用并维持这种理想的形态仍然存在争议和悬而未决。当鱼群可以自由地在三维空间中自我组织时，它们喜欢什么样的队形？通过跟踪连续游泳10小时的巨型达尼欧（Devario aequipinnatus）两极分化鱼群，我们发现鱼类很少停留在水平面上，更很少停留在经典的菱形地层中。在所有彼此距离在4个体长以内的鱼对中，只有25.2%的鱼对处于同一平面。其中，54.6%为行内排列，30.0%为交错排列，15.4%为并排排列。在不到0.1%的框架中观察到钻石形成。值得注意的是，垂直的“阶梯编队”是成群结队的巨型达尼奥鱼最可能的编队，出现在79%的鱼对中，并且在更高的游泳速度下它会拉长。这些发现强调了鱼群的动态和三维性质，并表明在不保持固定地层的情况下也可以获得水动力方面的好处。这项研究为未来研究三维地层中水下集体的流体动力学和控制提供了基础。

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Beyond planar: fish schools adopt ladder formations in 3D.

The coordinated movement of fish schools has long captivated researchers studying animal collective behavior. Classical literature from Weihs and Lighthill suggests that fish schools should favor planar diamond formations to increase hydrodynamic efficiency, inspiring a large body of work ranging from fluid simulations to hydrofoil experiments. However, whether fish schools actually adopt and maintain this idealized formation remains debated and unresolved. When fish schools are free to self-organize in three dimensions, what formations do they prefer? By tracking polarized schools of giant danios (Devario aequipinnatus) swimming continuously for ten hours, we demonstrate that fish rarely stay in a horizontal plane, and even more rarely, in the classical diamond formation. Of all fish pairs within four body-lengths from each other, only 25.2% were in the same plane. Of these, 54.6% were inline, 30.0% were staggered, and 15.4% were side-by-side. The diamond formation was observed in less than 0.1% of all frames. Notably, a vertical "ladder formation" emerged as the most probable formation for schooling giant danios, appearing in 79% of all fish pairs, and it elongated at higher swimming speeds. These findings highlight the dynamic and three-dimensional nature of fish schools and suggest that hydrodynamic benefits may be obtained without maintaining fixed formations. This research provides a foundation for future studies that examine the hydrodynamics and control of underwater collectives in 3D formations.

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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