Slip on superhydrophobic surfaces

Annual Review of Fluid Mechanics

Volumn 42, Issue , 2010, Pages 89-109

  Rothstein, Jonathan P ^a  

^a University of Massachusetts Amherst   (United States)

Author keywords

Drag reduction; Lotus effect; Ultrahydrophobic

Indexed keywords

FLUID-SOLID INTERFACES; LAMINAR AND TURBULENT FLOW; LOTUS EFFECT; LOTUS LEAF; OSMOTIC FLOW; SUPER-HYDROPHOBIC SURFACES; THEORY OF FLOW; ULTRAHYDROPHOBIC; WATER-REPELLENT PROPERTIES;

DRAG REDUCTION; LAMINAR FLOW; PHASE INTERFACES; SURFACE PROPERTIES; SURFACE ROUGHNESS;

HYDROPHOBICITY;

DRAG; EXPERIMENTAL STUDY; FLOW MODELING; HYDROPHOBICITY; INTERFACE; LAMINAR FLOW; OSMOSIS; SURFACE ROUGHNESS; TURBULENT FLOW;

EID: 77952827224     PISSN: 00664189     EISSN: None     Source Type: Book Series    
DOI: 10.1146/annurev-fluid-121108-145558     Document Type: Review

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