Water striders are impervious to raindrop collision forces and submerged by collapsing craters

Watson, Daren A.; Thornton, Mason R.; Khan, Hiba A.; Diamco, Ryan C.; Yilmaz-Aydin, Duygu; Dickerson, Andrew K.

doi:10.1073/pnas.2315667121

Proc. Natl. Acad. Sci. U.S.A.

2024

DOI: 10.1073/pnas.2315667121

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Water striders are impervious to raindrop collision forces and submerged by collapsing craters

Daren A. Watson,

Mason R. Thornton,

Hiba A. Khan

et al.

Abstract: Water striders are abundant in areas with high humidity and rainfall. Raindrops can weigh more than 40 times the adult water strider and some pelagic species spend their entire lives at sea, never contacting ground. Until now, researchers have not systematically investigated the survival of water striders when impacted by raindrops. In this experimental study, we use high-speed videography to film drop impacts on water striders. Drops force the insects subsurface upon direct contact. As the ensuing crater rebo… Show more

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2024

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Cited by 3 publications

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Enhancing Resistance to Wetting Transition through the Concave Structures

Lee,

Park,

Jung

et al. 2024

Advanced Materials

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Water‐repellent superhydrophobic surfaces are ubiquitous in nature. The fundamental understanding of bio/bio‐inspired structures facilitates practical applications surmounting metastable superhydrophobicity. Typically, the hierarchical structure and/or reentrant morphology have been employed hitherto to suppress the Cassie‐Baxter to Wenzel transition (CWT). Herein, a new design concept is reported, an effect of concave structure, which is vital for the stable superhydrophobic surface. The thermodynamic and kinetic stabilities of the concave pillars are evaluated by continuous exposure to various hydrostatic pressures and sudden impacts of water droplets with various Weber numbers (We), comparing them to the standard superhydrophobic normal pillars. Specifically, the concave pillar exhibits reinforced impact resistance preventing CWT below a critical We of ≈27.6, which is ≈1.6 times higher than that of the normal pillar (≈17.0). Subsequently, the stability of underwater air film (plastron) is investigated at various hydrostatic pressures. The results show that convex air caps formed at the concave cavities generate downward Laplace pressure opposing the exerted hydrostatic pressure between the pillars, thus impeding the hydrostatic pressure‐dependent underwater air diffusion. Hence, the effects of trapped air caps contributing to the stable Cassie‐Baxter state can offer a pioneering strategy for the exploration and utilization of superhydrophobic surfaces.

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Enhancing Resistance to Wetting Transition through the Concave Structures

Lee,

Park,

Jung

et al. 2024

Advanced Materials

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Compound cavity formation and splash crown suppression by water entry through proximally adjacent polystyrene beads

Watson,

Anzola,

Zeas

et al. 2024

Physics of Fluids

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We move forward the important topic of water entry by documenting splash dynamics arising from the impact of hydrophilic spheres with buoyant millimetric microplastics, mimicked in our study by polystyrene beads. Collision with small, buoyant beads is yet another means to manipulate splash dynamics. In this experimental study, we investigate the fluid–structure interactions between beads and hydrophilic spheres for Froude numbers in the range of 20−100. Generally, hydrophilic spheres entering a liquid bath below the critical velocity of 8 m/s produce minimal fluid displacement and no cavity formation. The presence of proximally adjacent beads atop the fluid with respect to impacting spheres promote flow separation and compound cavities for sufficiently large Froude numbers, while suppressing the growth of splash crowns. Compound cavities consist of a shallow, quasi-static first cavity that seals near the water line, and a second, deeper cavity produced in the wake of descending spheres. A vertically protruding Worthington jet follows cavity collapse. The resulting splash metrics differ from those of hydrophobic spheres with respect to the properties of impacted beads. We find impactors traversing a deep liquid pool layered with beads experience drag reduction when compared to entry into a clean pool due to the drag-reducing benefits of flow separation while not offering a high inertial penalty. Our study unravels the physics behind the widely encountered interaction of solid projectiles impacting passively floating particles, and our results translate to the entry dynamics of water-diving creatures and projectiles into water bodies polluted by floating millimetric microplastics.

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Rainproof Water Striders

Rini

2024

Physics

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Water striders are impervious to raindrop collision forces and submerged by collapsing craters

Cited by 3 publications

References 55 publications

Enhancing Resistance to Wetting Transition through the Concave Structures

Enhancing Resistance to Wetting Transition through the Concave Structures

Compound cavity formation and splash crown suppression by water entry through proximally adjacent polystyrene beads

Rainproof Water Striders

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