Preliminary Investigation of the Frictional Response of Reptilian Shed Skin

TL;DR

This study investigates how shed snake skin exhibits direction-dependent frictional behavior, revealing anisotropic properties likely due to microscopic structural asymmetries, which could inspire bio-inspired surface designs.

Contribution

It provides the first in vivo measurement of frictional anisotropy in snake shed skin using a novel tribo-acoustic probe, linking surface microstructure to tribological behavior.

Findings

Friction coefficient varies with sliding direction, lower in forward motion.

Frictional anisotropy is confirmed through in vivo measurements.

Asymmetry in fibril profile may cause directional friction differences.

Abstract

Developing deterministic surfaces relies on controlling the structure of the rubbing interface so that not only the surface is of optimized topography, but also is able to self-adjust its tribological behaviour according to the evolution of sliding conditions. In seeking inspirations for such designs, many engineers are turning toward the biological world to correlate surface structure to functional behavior of bio-analogues. From a tribological point of view, squamate reptiles offer diverse examples where surface texturing, submicron and nano-scale features, achieve frictional regulation. In this paper, we study the frictional response of shed skin obtained from a snake (Python regius). The study employed a specially designed tribo-acoustic probe capable of measuring the coefficient of friction and detecting the acoustical behavior of the skin in vivo. The results confirm the anisotropy of the frictional response of snakes. The coefficient of friction depends on the direction of sliding: the value in forward motion is lower than that in the backward direction. In addition it is shown that the anisotropy of the frictional response may stem from profile asymmetry of the individual fibril structures present within the ventral scales of the reptile