Emergent oscillations assist obstacle negotiation during ant cooperative transport

Collective motion by animal groups is affected by internal interactions, external constraints, and the influx of information. A quantitative understanding of how these different factors give rise to different modes of collective motion is, at present, lacking. Here, we study how ants that cooperativ...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2016-12, Vol.113 (51), p.14615-14620
Main Authors: Gelblum, Aviram, Pinkoviezky, Itai, Fonio, Ehud, Gov, Nir S., Feinerman, Ofer
Format: Article
Language:English
Subjects:
Biological Sciences
Experiments
Formicidae
Insects
Mathematical models
Motor ability
Physical Sciences
Physics
Quantitative analysis
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Summary:Collective motion by animal groups is affected by internal interactions, external constraints, and the influx of information. A quantitative understanding of how these different factors give rise to different modes of collective motion is, at present, lacking. Here, we study how ants that cooperatively transport a large food item react to an obstacle blocking their path. Combining experiments with a statistical physics model of mechanically coupled active agents, we show that the constraint induces a deterministic collective oscillatory mode that facilitates obstacle circumvention. We provide direct experimental evidence, backed by theory, that this motion is an emergent group effect that does not require any behavioral changes at the individual level. We trace these relaxation oscillations to the interplay between two forces; informed ants pull the load toward the nest whereas uninformed ants contribute to the motion’s persistence along the tangential direction. The model’s predictions that oscillations appear above a critical system size, that the group can spontaneously transition into its ordered phase, and that the system can exhibit complete rotations are all verified experimentally. We expect that similar oscillatory modes emerge in collective motion scenarios where the structure of the environment imposes conflicts between individually held information and the group’s tendency for cohesiveness.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1611509113