Strength-mass scaling law governs mass distribution inside honey bee swarms

To survive during colony reproduction, bees create dense clusters of thousands of suspended individuals. How does this swarm, which is orders of magnitude larger than the size of an individual, maintain mechanical stability? We hypothesize that the internal structure in the bulk of the swarm, about which there is little prior information, plays a key role in mechanical stability. Here, we provide the first-ever 3D reconstructions of the positions of the bees in the bulk of the swarm using x-ray computed tomography. We find that the mass of bees in a layer decreases with distance from the attachment surface. By quantifying the distribution of bees within swarms varying in size (made up of 4000-10,000 bees), we find that the same power law governs the smallest and largest swarms, with the weight supported by each layer scaling with the mass of each layer to the approximate to 1.5 power. This arrangement ensures that each layer exerts the same fraction of its total strength, and on average a bee supports a lower weight than its maximum grip strength. This illustrates the extension of the scaling law relating weight to strength of single organisms to the weight distribution within a superorganism made up of thousands of individuals.

Automated summary

To understand how swarms of bees maintain mechanical stability during colony reproduction, researchers conducted the first-ever 3D reconstructions of the bee positions in the swarm using x-ray computed tomography. They found that the mass of bees in a layer decreases with distance from the attachment surface, and discovered that a power law governs the weight distribution within swarms of different sizes. This power law ensures that each layer exerts the same proportion of its total strength, allowing bees to support lower weight than their maximum grip strength.