Climbing, falling and jamming during ant locomotion in confined environments

TL;DR

This study investigates how fire ants navigate confined tunnels, revealing their ability to recover from falls by jamming against tunnel walls, with implications for understanding biological locomotion and designing confined-space robots.

Contribution

It provides new insights into ant locomotion in confined spaces, identifying a critical tunnel diameter for fall arrest and linking tunnel size to natural nest construction.

Findings

Ants move rapidly within tunnels comparable to their body size.

Falls below a critical tunnel diameter are always arrested by wall interactions.

Tunnel size in natural nests aligns with the critical diameter for fall arrest.

Abstract

Locomotion emerges from effective interactions of an individual with its environment. Principles of biological terrestrial locomotion have been discovered on unconfined vertical and horizontal substrates. However a diversity of organisms construct, inhabit, and move within confined spaces. Such animals are faced with locomotor challenges including limited limb range of motion, crowding, and visual sensory deprivation. Little is known about how these organisms accomplish their locomotor tasks, and such environments challenge human-made devices. To gain greater insight into how animals move within confined spaces we study the confined locomotion of the fire ant {\em Solenopsis invicta}, which constructs subterranean tunnel networks (nests). Laboratory experiments reveal that ants construct tunnels with diameter, D, comparable to bodylength, L=3.5 $\pm$ 0.5 mm. Ants can move rapidly (> 9 bodylengths/sec) within these environments; their tunnels allow for effective limb, body, and antennae interaction with walls which facilitate rapid slip-recovery during ascending and descending climbs. To examine the limits of slip-recovery in artificial tunnels we perform perturbations consisting of rapid downward accelerations of the tunnels, which induce falls. Below a critical tunnel diameter, $D_s = 1.31 \pm 0.02$ L, falls are always arrested through rapid interaction of appendages and antennae with tunnel walls to jam the falls. $D_s$ is comparable to the size of incipient nest tunnels (D = 1.06 $\pm$ 0.23 L) supporting our hypothesis that fire ants construct environments which simplify their control task when moving through the nest, likely without need for rapid nervous system intervention.