Passive bristling of mako shark scales in reversing flows

Clos, Kevin T. Du; Lang, Amy; Devey, Sean; Motta, Philip; Habegger, María Laura; Gemmell, Brad J.

doi:10.1098/rsif.2018.0473

Cited by 27 publications

(20 citation statements)

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“…5 The reason for the passive bristling of shark denticles in reversing the ows has been described by Du Clos et al, who explained the downward backow between the denticles and the vortex above the denticles were associated with passive bristling by a high-speed camera. 50 Some adverse factors, such as backow, can be inhibited by the passive bristling of shark denticles. The study suggested that shark skin denticles may absorb the negative energy of backow by passive bristling and delay the onset of turbulence in the boundary layer.…”

Section: ) 41mentioning

confidence: 99%

Thriving artificial underwater drag-reduction materials inspired from aquatic animals: progresses and challenges

et al. 2021

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Section: ) 41mentioning

confidence: 99%

Thriving artificial underwater drag-reduction materials inspired from aquatic animals: progresses and challenges

et al. 2021

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“…The first is that riblets can reduce momentum transfer and shear stress by preventing cross-flow over the scales ( Bechert et al, 2000b ). The second is that the scales are flexible and capable of bristling to stop reversed flow across the skin surface ( Lang et al, 2011 ; Du Clos et al, 2018 ; Santos et al, 2021 ). NASA Langley Research Center ( Walsh and Weinstein, 1978 ) has carried out research on the drag reduction performance of ribbed surfaces.…”

Section: Introductionmentioning

confidence: 99%

Relationship Between Skin Scales and the Main Flow Field Around the Shortfin Mako Shark Isurus oxyrinchus

Zhang

Gao

Liu

et al. 2022

Front. Bioeng. Biotechnol.

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The aim of this study was to reveal potential relationship between the main flow field around a shortfin mako shark and the surface morphology of shark skin. Firstly, a numerical simulation using the large eddy simulation (LES) method was conducted to obtain the main flow field around a smooth shark model. Then, the surface morphology characteristics of a shark (Isurus oxyrinchus) at different positions were characterized by scanning electron microscope (SEM), which showed that the morphology, riblet size, and density of scales at different positions on the shark were significantly different. At positions where the surfaces face into the water flow direction (i.e., nose and leading edge of fins), the scales were flat and round, with a lower density, and the pressure or wall shear stress (WSS) was greater. Scales with three longitudinal riblets ending in three tips were found on the middle and trailing edges of the first dorsal fin and caudal fin, where water flow states progress from transitional to turbulent. The ranges of the ratio of riblet depth to spacing (RD/RS) in the anterior zone, middle zone and posterior zone of the shark were 0.05–0.17, 0.08–0.23, and 0.32–0.33, respectively. The riblet angle generally followed the flow direction, but it varied across different areas of the body. The turbulence intensity increased gradually across the first dorsal fin, pectoral fin, caudal fin, and the shark body overall. In summary, it was found that the microstructure riblets on the shark skin surface, generally thought to be drag reduction structures, were only located in transitional and turbulent regions at the middle and trailing edge of the shark body and fin surfaces, and there were almost no microstructural grooves in the laminar flow regions along the leading edge. These findings can provide design guidance for engineering applications of bionic riblet surfaces. Riblets placed in transitional and fully turbulent regions can be used to effectively reduce drag. The riblet direction should be consistent with the direction of flow.

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“…One function that has been an important focus for research is the role of denticles in support of locomotion, as many extant shark species have denticles with morphologies that improve swimming performance. Fluid dynamic studies have revealed that denticles can improve swimming performance by enhancing thrust, reducing hydrodynamic drag, as well as changing the boundary layer characteristics of water flow over the body ( DuClos et al. 2018 ; Lang et al.…”

Section: Introductionmentioning

confidence: 99%

Dermal Denticle Diversity in Sharks: Novel Patterns on the Interbranchial Skin

Gabler-Smith

Wainwright

Wong

et al. 2021

Integrative Organismal Biology

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Shark skin is covered in dermal denticles – tooth-like structures consisting of enameloid, dentine, and a central pulp cavity. Previous studies have demonstrated differences in denticle morphology both among species and across different body regions within a species, including one report of extreme morphological variation within a 1 cm distance on the skin covering the branchial pouches, a region termed “interbranchial skin”. We used gel-based profilometry, histology, and scanning electron microscopy to quantify differences in denticle morphology and surface topography of interbranchial skin denticles among 13 species of sharks to better understand the surface structure of this region. We show that 1) interbranchial skin denticles differ across shark species, and 2) denticles on the leading edge of the skin covering each gill pouch have different morphology and surface topography compared to denticles on the trailing edge. Across all species studied, there were significant differences in denticle length (P = 0.01) and width (P = 0.002), with shorter and wider leading edge denticles compared to trailing edge denticles. Surface skew was also higher in leading edge denticles (P = 0.009), though most values were still negative, indicating more valleys than peaks. Overall, leading edge denticles were smoother-edged than trailing edge denticles in all of the species studied. These data suggest two hypotheses: 1) smoother-edged leading edge denticles protect the previous gill flap from abrasion during respiration, and 2) ridged denticle morphology at the trailing edge might alter water turbulence exiting branchial pouches after passing over the gills. Future studies will focus on determining the relationship between denticle morphology and water flow by visualizing fluid motion over interbranchial denticles during in vivo respiration.

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Passive bristling of mako shark scales in reversing flows

Cited by 27 publications

References 50 publications

Thriving artificial underwater drag-reduction materials inspired from aquatic animals: progresses and challenges

Thriving artificial underwater drag-reduction materials inspired from aquatic animals: progresses and challenges

Relationship Between Skin Scales and the Main Flow Field Around the Shortfin Mako Shark Isurus oxyrinchus

Dermal Denticle Diversity in Sharks: Novel Patterns on the Interbranchial Skin

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