• DocumentCode
    1403584
  • Title

    Influence of surface roughness on wet adhesion of biomimetic adhesive pads with planar microstructures

  • Author

    Kun Wang ; Bin He ; Run-Jie Shen

  • Author_Institution
    Coll. of Mech. Eng., Tongji Univ., Shanghai, China
  • Volume
    7
  • Issue
    12
  • fYear
    2012
  • fDate
    12/1/2012 12:00:00 AM
  • Firstpage
    1274
  • Lastpage
    1277
  • Abstract
    Biological adhesive pads of some reptiles and insects, such as tree frogs and grasshoppers, are covered with planar microstructures and have strong and stable adhesive ability on both wet and dry substrates. These adhesion forces do not mainly come from van-der-Waals force but wet adhesion. In this study, the influence of substrates´ surface roughness on the wet adhesion of man-made adhesive pads inspired by tree frog toe pads is investigated experimentally. Biomimetic polydimethylsiloxane adhesive pads with planar hexagon microstructures with a microchannels width of 10 μm are fabricated by combining electroforming with soft lithography. Experiments of wet adhesive force between the pads and sandpaper slices with different average surface roughness are carried out at various preloads. Results show that the rougher surface leads to the decrement of wet adhesion force. It is also observed that if the microcosmic profile height of the substrates is near or less than the width of microchannels in the biomimetic adhesive pads, the microstructures and preloads can increase significantly the wet adhesive force, otherwise the microstructures and preloads do not contribute indistinctively. The experimental results can be explained by analysing the relation between the solid contact area and the area with a liquid bridge.
  • Keywords
    adhesion; adhesives; biomimetics; electroforming; microfabrication; polymers; soft lithography; surface roughness; van der Waals forces; biological adhesive pads; biomimetic polydimethylsiloxane adhesive pads; dry substrates; electroforming; grasshoppers; insects; liquid bridge area; man-made adhesive pads; microchannels; microcosmic profile height; planar hexagon microstructures; reptiles; sandpaper slices; size 10 mum; soft lithography; solid contact area; stable adhesive ability; surface roughness; tree frog toe pads; van-der-Waals force; wet adhesion force; wet adhesive force; wet substrates;
  • fLanguage
    English
  • Journal_Title
    Micro & Nano Letters, IET
  • Publisher
    iet
  • ISSN
    1750-0443
  • Type

    jour

  • DOI
    10.1049/mnl.2012.0683
  • Filename
    6419612