Propulsion on a superhydrophobic ratchet

Dupeux, Guillaume; Bourrianne, Philippe; Magdelaine, Quentin; Clanet, Christophe; Quéré, David

doi:10.1038/srep05280

Cited by 52 publications

(45 citation statements)

References 14 publications

(27 reference statements)

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“…Distilled water meets these substrates with an advancing angle of θ A ≈ 171 ± 2 • and a receding angle of θ R ≈ 165 ± 2 • . These high values and the corresponding low hysteresis θ = θ A − θ R ≈ 6 • characterize a superhydrophobic Cassie state: liquid only contacts the tops of the hydrophobic colloids, which minimizes the pinning of contact lines and viscous dissipation (Gogte et al 2005;Olin et al 2013;Dupeux et al 2014). In such a state, the height H of a puddle becomes nearly independent of the contact angle and it tends towards twice the capillary length 2a = 2(γ /ρg) 1/2 (i.e.…”

Section: Observationsmentioning

confidence: 97%

Retraction of large liquid strips

Clanet

Quéré

2015

J. Fluid Mech.

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International audienceWe study the behaviour of elongated puddles deposited on non-wetting substrates. Such liquid strips retract and adopt circular shapes after a few oscillations. Their thickness and horizontal surface area remain constant during this reorganization, so that the energy of the system is only lowered by minimizing the length of the contour (and the corresponding surface energy); despite the large scale of the experiments (several centimetres), motion is driven by surface tension. We focus on the retraction stage, and show that its velocity results from a balance between the capillary driving force and inertia, due to the frictionless motion on non-wetting substrates. As a consequence, the retraction velocity has a special Taylor-Culick structure, where the puddle width replaces the usual thickness

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Section: Observationsmentioning

confidence: 97%

Retraction of large liquid strips

Clanet

Quéré

2015

J. Fluid Mech.

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“…[ 44 ] Note that the formation of an integral fi lm during the Leidenfrost regime is not benefi cial for evaporation-based thermal management applications such as in the spray cooling of electronic devices. On surfaces with larger ratchet structures, [162][163][164] the vapor fl ow is dominant and the Leidenfrost drop shifts against the tilted direction, whereas the drop moves along the tilted direction for surfaces with tiny features (Figure 6 e). [ 165,166 ] Li et al reported that a directional rebounding towards the higher heat transfer region can be achieved through breaking the wetting symmetry at high temperature.…”

Section: The Effect Of Air Lubrication For Fast Drop Bouncingmentioning

confidence: 99%

Bioinspired Interfacial Materials with Enhanced Drop Mobility: From Fundamentals to Multifunctional Applications

Hao

Liu

Chen

et al. 2016

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The development of bioinspired interfacial materials with enhanced drop mobility that mimic the innate functionalities of nature will have a significant impact on the energy, environment and global healthcare. Despite extensive progress, state of the art interfacial materials have not reached the level of maturity sufficient for industrial applications in terms of scalability, stability, and reliability. These are complicated by their operating environments and lack of facile approaches to control the local structural texture and chemical composition at multiple length scales. The recent advances in the fundamental understanding are reviewed, as well as practical applications of bioinspired interfacial materials, with an emphasis on the drop bouncing and coalescence-induced jumping behaviors. Perspectives on how to catalyze new discoveries and to foster technological adoption to move this exciting area forward are also suggested.

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“…Moreover, Grounds et al [19] have experimentally studied the processes that Leidenfrost droplets climb uphill on tilted ratchet surfaces with different sub-structures. Recently, Dupeux et al [20] reported that the water droplets can be propelled far below the usual Leidenfrost temperature when using textured superhydrophobic ratchets, which extends the parameter range where self-propulsion can be obtained. Using a low pressure environment, Celestini et al [21] found that the Leidenfrost droplets of water can be generated at room temperature.…”

Section: Introductionmentioning

confidence: 96%

Lattice Boltzmann modeling of self-propelled Leidenfrost droplets on ratchet surfaces

Kang

François

et al. 2016

Soft Matter

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In this paper, the self-propelled motion of Leidenfrost droplets on ratchet surfaces is numerically investigated using a thermal multiphase lattice Boltzmann model with liquid-vapor phase change. The capability of the model for simulating evaporation is validated via the D(2) law. Using the model, we first study the performances of Leidenfrost droplets on horizontal ratchet surfaces. It is numerically shown that the motion of self-propelled Leidenfrost droplets on ratchet surfaces is owing to the asymmetry of the ratchets and the vapor flows beneath the droplets. It is found that the Leidenfrost droplets move in the direction toward the slowly inclined side from the ratchet peaks, which agrees with the direction of droplet motion in experiments [Linke et al., Phys. Rev. Lett., 2006, 96, 154502]. Moreover, the influences of the ratchet aspect ratio are investigated. For the considered ratchet surfaces, a critical value of the ratchet aspect ratio is approximately found, which corresponds to the maximum droplet moving velocity. Furthermore, the processes that the Leidenfrost droplets climb uphill on inclined ratchet surfaces are also studied. Numerical results show that the maximum inclination angle at which a Leidenfrost droplet can still climb uphill successfully is affected by the initial radius of the droplet.

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Propulsion on a superhydrophobic ratchet

Cited by 52 publications

References 14 publications

Retraction of large liquid strips

Retraction of large liquid strips

Bioinspired Interfacial Materials with Enhanced Drop Mobility: From Fundamentals to Multifunctional Applications

Lattice Boltzmann modeling of self-propelled Leidenfrost droplets on ratchet surfaces

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