The local slip length and flow fields over nanostructured superhydrophobic surfaces

Bao, Luyao; Priezjev, Nikolai V.; Hu, Haibao

doi:10.1016/j.ijmultiphaseflow.2020.103258

Cited by 12 publications

(3 citation statements)

References 57 publications

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“…In another series of studies, the channel height has been carefully adjusted to maintain a flat liquid/air interface in molecular dynamics simulations (Bao, Priezjev & Hu 2020;Ren et al 2021). Using certain microtrench SH surfaces, the Cassie state has been stabilized for turbulent flows (Xu et al 2020(Xu et al , 2021.…”

Section: Introductionmentioning

confidence: 99%

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Poiseuille flow of a Bingham fluid in a channel with a superhydrophobic groovy wall

Rahmani

Taghavi

2022

J. Fluid Mech.

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Plane Poiseuille flow of a Bingham fluid in a channel armed with a superhydrophobic (SH) lower wall is analysed via a semi-analytical model, accompanied by complementary direct numerical simulations (DNS). The SH surface represents a groovy structure with air trapped inside its cavities. Therefore, the fluid adjacent to the wall undergoes stick–slip conditions. The model is developed based on introducing infinitesimal wall-induced perturbations into the motion equations, followed by Fourier series expansions, and solving the resulting equations as a boundary value problem. The Navier slip law accounts for the slip at the liquid/air interface (assuming the Cassie state). The presented analysis is fairly comprehensive, covering the creeping and inertial regimes for thick channels (via the semi-analytical and DNS solutions). The main dimensionless numbers are the Reynolds ( $Re$ ), Bingham ( $Bi$ ) and slip ( $b$ ) numbers, as well as the groove periodicity length ( $\ell$ ) and the slip area fraction ( $\varphi$ ). By increasing $Bi$ , the perturbation and slip velocity fields grow. As $Re$ increases, the perturbation and slip velocity fields become asymmetric. For certain flow parameters, an unyielded plug zone may appear on the SH wall liquid/air interface, while its formation is accelerated by inertial effects. The results classify the regimes of creeping and inertial flows via predicting the onset of the unyielded plug zone formation at the SH wall.

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Section: Introductionmentioning

confidence: 99%

“…2019). In another series of studies, the channel height has been carefully adjusted to maintain a flat liquid/air interface in molecular dynamics simulations (Bao, Priezjev & Hu 2020; Ren et al. 2021).…”

Section: Introductionmentioning

confidence: 99%

Poiseuille flow of a Bingham fluid in a channel with a superhydrophobic groovy wall

Rahmani

Taghavi

2022

J. Fluid Mech.

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“…Nevertheless, an excessively large groove width is not conducive to drag reduction. Bao et al [85] found that the relationship between local and effective slip length is not consistent with the continuity hypothesis for both lateral and longitudinal layouts The slip length, l S , and temperature jump coefficient, k S , commonly used to address the slip at the surface. Reproduced with permission.…”

Section: Layout and Shape Of The Microstructuresmentioning

confidence: 99%

Recent Developments of Superhydrophobic Surfaces (SHS) for Underwater Drag Reduction Opportunities and Challenges

Feng

Sun

Tian

2021

Adv Materials Inter

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Superhydrophobic surfaces (SHS) for underwater drag reduction draw more and more attention owing to its promising and wide applications such as underwater vehicles, pipeline oil transportation, and aquaculture. However, the drag reduction properties are inextricably linked to the stability of air layer on SHS. This review highlights recent advances regarding SHS for underwater drag reduction in the past three years. First, the fundamental theories are briefly described. Next, the crucial influencing factors, which include dimension and arrangement of particles, layout, and shape of the microstructures, Reynolds number, and attack angle on underwater drag reducing performance of SHS are thoroughly listed. Furthermore, the superior or inferior of these manufacturing techniques is also individually illustrated. After that, the solutions of enhancing stability of the air layer are explicitly classified. Then, the practical applications and its potential value in ships and underwater vehicles, microchannels, as well as fabrics are briefly discussed. Finally, the remaining challenges and promising breakthroughs in the field of SHS for underwater drag reduction are clarified in depth.

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Research progress of slippage characteristic and gas film stability enhancement methods on biomimetic hydrophobic surfaces

Zhang,

Hu,

Ren

et al. 2024

J Hydrodyn

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The local slip length and flow fields over nanostructured superhydrophobic surfaces

Cited by 12 publications

References 57 publications

Poiseuille flow of a Bingham fluid in a channel with a superhydrophobic groovy wall

Poiseuille flow of a Bingham fluid in a channel with a superhydrophobic groovy wall

Recent Developments of Superhydrophobic Surfaces (SHS) for Underwater Drag Reduction Opportunities and Challenges

Research progress of slippage characteristic and gas film stability enhancement methods on biomimetic hydrophobic surfaces

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