Abstract
Ants are able to climb effortlessly on vertical and inverted smooth surfaces. When climbing, their feet touch the substrate not only with their pretarsal adhesive pads but also with dense arrays of fine hairs on the ventral side of the 3rd and 4th tarsal segments. To understand what role these different attachment structures play during locomotion, we analysed leg kinematics and recorded single-leg ground reaction forces in Weaver ants (Oecophylla smaragdina) climbing vertically on a smooth glass substrate. We found that the ants engaged different attachment structures depending on whether their feet were above or below their Centre of Mass (CoM). Legs above the CoM pulled and engaged the arolia (‘toes’), whereas legs below the CoM pushed with the 3rd and 4th tarsomeres (‘heels’) in surface contact. Legs above the CoM carried a significantly larger proportion of the body weight than legs below the CoM. Force measurements on individual ant tarsi showed that friction increased with normal load as a result of the bending and increasing side contact of the tarsal hairs. On a rough sandpaper substrate, the tarsal hairs generated higher friction forces in the pushing than in the pulling direction, whereas the reverse effect was found on the smooth substrate. When the tarsal hairs were pushed, buckling was observed for forces exceeding the shear forces found in climbing ants. Adhesion forces were small but not negligible, and higher on the smooth substrate. Our results indicate that the dense tarsal hair arrays produce friction forces when pressed against the substrate, and help the ants to push outwards during horizontal and vertical walking.
Highlights
Many animals have evolved specialised adhesive pads on their feet to climb on smooth surfaces
No evidence of a contact was found in the recordings of the surface of the platform. This indicates that the claw flexor muscle was mostly relaxed and the tarsomeres were in their raised default position
Our results show that weaver ants use different parts of their foot in different climbing situations
Summary
Many animals have evolved specialised adhesive pads on their feet to climb on smooth surfaces. These pads are either soft and have a relatively smooth surface (‘smooth’ pads) or they consist of a brush-like array of fine hairs (‘hairy’ pads). Most animal adhesive structures are direction-dependent, i.e. they attach only when pulled towards the body but detach when pushed away from it. Such directionality has been found across a wide variety of taxa, including flies [1], bush crickets [2], ants [3, 4], cockroaches [5], PLOS ONE | DOI:10.1371/journal.pone.0141269. Such directionality has been found across a wide variety of taxa, including flies [1], bush crickets [2], ants [3, 4], cockroaches [5], PLOS ONE | DOI:10.1371/journal.pone.0141269 November 11, 2015
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