Penguins exploit tidal currents for efficient navigation and opportunistic foraging.

IF 9.8 1区生物学 Q1 Agricultural and Biological Sciences

PLoS Biology Pub Date : 2025-07-17 eCollection Date: 2025-07-01 DOI:10.1371/journal.pbio.3002981

Richard M Gunner, Flavio Quintana, Mariano H Tonini, Mark D Holton, Ken Yoda, Margaret C Crofoot, Rory P Wilson

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引用次数: 0

Abstract

Animals navigating in fluid environments often face forces from wind or water currents that challenge travel efficiency and route accuracy. We investigated how 27 Magellanic penguins (Spheniscus magellanicus) adapt their navigation strategies to return to their colony amid regional tidal ocean currents. Using GPS-enhanced dead-reckoning loggers and high-resolution ocean current data, we reconstructed penguin travel vectors during foraging trips to assess their responses to variable currents during their colony-bound movements. By integrating estimates of energy costs and prey pursuits, we found that birds balanced direct navigation with current-driven drift: in calm currents, they maintained precise line-of-sight headings to their colony. In stronger currents, they aligned their return with lateral flows, which increased travel distance, but at reduced energy costs, and provided them with increased foraging opportunities. Since the lateral tidal currents always reversed direction over the course of return paths, the penguins' return paths were consistently S-shaped but still resulted in the birds returning efficiently to their colonies. These findings suggest that Magellanic penguins can sense current drift and use it to enhance energy efficiency by maintaining overall directional accuracy while capitalizing on foraging opportunities.

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企鹅利用潮流进行有效的导航和觅食。

在流体环境中航行的动物经常面临来自风或水流的力量，这挑战了旅行的效率和路线的准确性。我们研究了27只麦哲伦企鹅（Spheniscus magellanicus）如何在区域潮汐洋流中调整它们的导航策略以返回它们的殖民地。利用gps增强的航位推算记录仪和高分辨率洋流数据，我们重建了企鹅觅食旅行中的旅行向量，以评估它们在种群移动过程中对可变洋流的反应。通过综合对能量消耗和猎物追击的估计，我们发现鸟类在直接导航和水流驱动的漂移之间取得了平衡：在平静的水流中，它们保持了对种群的精确视线。在较强的水流中，它们沿着横向流返回，这增加了旅行距离，但减少了能量消耗，并为它们提供了更多的觅食机会。由于侧向潮流在返回路径上总是相反的方向，企鹅的返回路径始终是s形的，但仍然导致鸟类有效地返回到它们的栖息地。这些发现表明，麦哲伦企鹅可以感知洋流的漂移，并在利用觅食机会的同时，通过保持整体方向的准确性来提高能量效率。

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

PLoS Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-BIOLOGY

CiteScore

15.40

自引率

2.00%

发文量

359

审稿时长

3-8 weeks

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