Washington [US], June 18 (ANI): A new study by an international team of researchers is the first to show that the characteristics of the hair-like structures that form the adhesive feet of one species- the wandering spider Cupiennius salei- are more variable than previously thought.
Just how do spiders walk straight up and even upside-down across -- so many different types of surfaces? Findings published in the journal Frontiers in Mechanical Engineering have answered these questions to up new opportunities for creating powerful, yet reversible, bioinspired adhesives.
Scientists have been working to better understand spider feet for the past several decades.
"When we started the experiments, we expected to find a specific angle of best adhesion and similar adhesive properties for all of the individual attachment hairs," said the group leader of the study, Dr Clemens Schaber of the University of Kiel in Germany.
He added, "But surprisingly, the adhesion forces largely differed between the individual hairs, e.g. one hair adhered best at a low angle with the substrate while the other one performed best close to perpendicular."
The feet of this species of spider is made up of close to 2,400 tiny hairs or 'setae' (one-hundredth of one millimetre thick). Schaber, and his colleagues Bastian Poerschke and Stanislav Gorb, collected a sample of these hairs and then measured how well they stuck to a range of rough and smooth surfaces, including glass. They also looked at how well the hairs performed at various contact angles.
Unexpectedly, each hair showed unique adhesive properties. When the team looked at the hairs under a powerful microscope, they also found that each one showed clearly different- and previously unrecognized- structural arrangements. The team believes that this variety may be key to how spiders can climb so many surface types.
This current work studied only a small number of the thousands of hairs on each foot, and it's beyond the scope of existing resources to consider studying them all. But the team expects that not all of the hairs are unique and that it might be possible to find clusters or repeating patterns instead.
"Although it is still very difficult to fabricate nanostructures like those of the spider--and especially to achieve the stability and reliability of the natural materials -- our findings can further optimize existing models for reversible and residue-free artificial adhesives," said Schaber.
He added, "The principle of different shapes and alignments of adhesive contacts as found in the spider attachment system can improve the attachment ability of bioinspired materials to a broad range of substrates with different properties." (ANI)