Optical properties of the jellyfish surface above the waterline: microvillar array in pleustonic hydrozoans.

IF 1.7 3区生物学 Q2 ZOOLOGY

Zoological Letters Pub Date : 2025-09-02 DOI:10.1186/s40851-025-00253-4

Euichi Hirose, Nicolò Brunelli, Daisuke Sakai, Hiroshi Kakiuchida, Jun Nishikawa

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引用次数: 0

Abstract

Background: The transparent jellyfish body is often difficult to see underwater, as its refractive index is similar to that of seawater, resulting in a low light reflectance on the body surface. Nevertheless, the outlines of jellyfish can be recognized by the slight reflection of light from their body surfaces. In some jellyfish species, the epidermis covering the body surface has an array of microvilli, nanostructures that can potentially reduce light reflection. However, the anti-reflective effect is minimal in water, as the difference in the refractive indices of tissue and seawater is so small that reflectance is low, even on flat surfaces. In jellyfish that have pneumatophores, structures used in floating and drifting on the sea surface, light reflection on the surface is expected to be large and noticeable owing to the large differences in refractive indices between the pneumatophore exposed above the water surface and air. In the current study, we examined the epidermal ultrastructure and refractive index of the pneumatophores of a Portuguese man o' war (Physalia physalis) and a by-the-wind sailor (Velella velella).

Results: The refractive index of P. physalis pneumatophores measured with an Abbe refractometer was approximately 1.344. Microvillar arrays were found in epidermal cells of both P. physalis and V. velella. Based on the length, thickness, and pitch of the microvilli, we constructed simplified structural models for the simulation of light reflection using rigorous coupled wave analysis (RCWA). Our simulations showed that reflectance on the microvillar models could be greater or less than that on the flat surface, depending on light conditions (wavelength and angle of incidence), but with an overall effect of reduced reflection. Reflection reduction in microvillar models was particularly significant at large incident angles, where reflectance was extremely high on the flat surface.

Conclusions: Microvillar arrays found on the epidermis potentially reduce surface reflections of the pneumatophore and contribute to the reduction in visibility of the pleustonic hydrozoans above the sea surface. Moreover, less reflection at the pneumatophore surface indicates greater transmission of light through transparent bodies, potentially providing a counter-illumination effect that obscures the shadow of the hydrozoan bodies, depending on the intensity of ambient light.

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海蜇在水线以上表面的光学特性：复膜水生动物的微绒毛阵列。

背景：透明的水母身体在水下往往很难看到，因为它的折射率与海水相似，导致身体表面的反射率很低。然而，水母的轮廓可以通过身体表面轻微的反射光来识别。在一些水母物种中，覆盖身体表面的表皮有一排微绒毛，这种纳米结构可以潜在地减少光反射。然而，在水中，抗反射效果是最小的，因为组织和海水的折射率差异很小，即使在平坦的表面上，反射率也很低。水母有气团（用于在海面上漂浮和漂流的结构），由于暴露在水面上的气团和空气之间的折射率差异很大，因此在海面上的光反射预计会很大且明显。在本研究中，我们检测了一个葡萄牙人（Physalia physalis）和一个靠风水手（Velella Velella）的肺细胞的表皮超微结构和折射率。结果：用Abbe折光仪测得physalis pneumatophres的折光率约为1.344。在physalis和velella的表皮细胞中都发现了微绒毛阵列。基于微绒毛的长度、厚度和节距，利用严格耦合波分析（RCWA）建立了光反射模拟的简化结构模型。我们的模拟表明，根据光照条件（波长和入射角），微绒毛模型上的反射率可能大于或小于平面上的反射率，但总体上具有减少反射的效果。在大入射角下，微别墅模型的反射减少尤为显著，在平面上反射率极高。结论：在表皮上发现的微绒毛阵列可能会减少气团的表面反射，并有助于降低海面以上的浮游动物的可见度。此外，气团表面的反射越少，表明光通过透明体的透射越大，这可能会产生一种反照明效应，使水生动物的阴影变得模糊，这取决于环境光的强度。

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

Zoological Letters Agricultural and Biological Sciences-Animal Science and Zoology

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： Zoological Letters is an open access journal that publishes new and important findings in the zoological sciences. As a sister journal to Zoological Science, Zoological Letters covers a wide range of basic fields of zoology, from taxonomy to bioinformatics. We also welcome submissions of paleontology reports as part of our effort to contribute to the development of new perspectives in evolutionary zoology. Our goal is to serve as a global publishing forum for fundamental researchers in all fields of zoology.