Delta wing design in earliest nektonic vertebrates

IF 5.2 1区生物学 Q1 BIOLOGY

Communications Biology Pub Date : 2024-09-16 DOI:10.1038/s42003-024-06837-8

Héctor Botella, Richard A. Fariña, Francisco Huera-Huarte

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Abstract

The colonization of the pelagic realm by the vertebrates represents one of the major transitions in the evolutionary success of the group and in the establishment of modern complex marine ecosystem. It has been traditionally related with the Devonian rise of jawed vertebrates, but new evidences indicate that first active swimmers, invading the water column, occurred within earlier armoured jawless fishes (“ostracoderms”). These “primitive” fishes lacked conventional fish control surfaces and the precise mechanism used to generate lift and stabilizing forces still remains unclear. We show that, because of their shape, the rigid cephalic shield of Pteraspidiformes, a group of Silurian-Devonian “ostracoderms”, generate significant forces for hydrodynamic lift. Particle Image Velocimetry and force measurements in a water channel shows that the flow over real-sized Pteraspidiformes models is similar to that over delta wings, dominated by the formation of leading-edge vortices resulting in enhanced vortex lift forces and delayed stall angles of attack. Additionally, experiments simulating ground effect show that Pteraspidiformes present better hydrodynamic performance under fully pelagic conditions than in a benthic scenario. This suggests that, lacking movable appendages other than the caudal fin, leading-edge vortices were exploited by earliest vertebrates to colonize the water column more than 400 Mya. Digital particle image velocimetry and force measurements in a water channel provide evidence that leading-edge vortices could be exploited by earliest vertebrates to colonize the water column more than 400 Mya.

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最早的近脊椎动物的三角翼设计

脊椎动物对水层的殖民是该类群进化成功和建立现代复杂海洋生态系统的主要转变之一。传统上，这与泥盆纪有颌脊椎动物的兴起有关，但新的证据表明，入侵水体的第一批活跃的游泳者出现在早期的无颌有甲鱼类（"梭鱼"）中。这些 "原始 "鱼类缺乏传统的鱼类控制面，用于产生升力和稳定力的精确机制仍不清楚。我们的研究表明，翼手目（志留纪-德文纪的一类 "ostracoderms"）的刚性头盾因其形状而产生巨大的水动力升力。水道中的粒子图像测速仪和力测量结果表明，实际大小的翼甲虫模型上的水流与三角翼上的水流相似，主要是前缘涡的形成导致涡升力增强和失速攻角延迟。此外，模拟地面效应的实验表明，翼甲鱼类在完全浮游条件下的水动力性能优于底栖情况。这表明，由于缺乏除尾鳍以外的可移动附肢，最早的脊椎动物利用前缘涡流在 400 多万年前的水体中定居。水道中的数字颗粒图像测速仪和力测量提供了证据，证明最早的脊椎动物可以利用前缘涡流在 400 多万年前的水体中定居。

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

Communications Biology Medicine-Medicine (miscellaneous)

CiteScore

8.60

自引率

1.70%

发文量

1233

审稿时长

13 weeks

期刊介绍： Communications Biology is an open access journal from Nature Research publishing high-quality research, reviews and commentary in all areas of the biological sciences. Research papers published by the journal represent significant advances bringing new biological insight to a specialized area of research.

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