Jonathan Glancy scite author profile

Jonathan Glancy

5Publications

51Citation Statements Received

149Citation Statements Given

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144

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University of Sheffield

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A Self-Organising Model of Thermoregulatory Huddling

et al. 2015

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Endotherms such as rats and mice huddle together to keep warm. The huddle is considered to be an example of a self-organising system, because complex properties of the collective group behaviour are thought to emerge spontaneously through simple interactions between individuals. Groups of rodent pups display two such emergent properties. First, huddling undergoes a ‘phase transition’, such that pups start to aggregate rapidly as the temperature of the environment falls below a critical temperature. Second, the huddle maintains a constant ‘pup flow’, where cooler pups at the periphery continually displace warmer pups at the centre. We set out to test whether these complex group behaviours can emerge spontaneously from local interactions between individuals. We designed a model using a minimal set of assumptions about how individual pups interact, by simply turning towards heat sources, and show in computer simulations that the model reproduces the first emergent property—the phase transition. However, this minimal model tends to produce an unnatural behaviour where several smaller aggregates emerge rather than one large huddle. We found that an extension of the minimal model to include heat exchange between pups allows the group to maintain one large huddle but eradicates the phase transition, whereas inclusion of an additional homeostatic term recovers the phase transition for large huddles. As an unanticipated consequence, the extended model also naturally gave rise to the second observed emergent property—a continuous pup flow. The model therefore serves as a minimal description of huddling as a self-organising system, and as an existence proof that group-level huddling dynamics emerge spontaneously through simple interactions between individuals. We derive a specific testable prediction: Increasing the capacity of the individual to generate or conserve heat will increase the range of ambient temperatures over which adaptive thermoregulatory huddling will emerge.

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How self-organization can guide evolution

2016

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Self-organization and natural selection are fundamental forces that shape the natural world. Substantial progress in understanding how these forces interact has been made through the study of abstract models. Further progress may be made by identifying a model system in which the interaction between self-organization and selection can be investigated empirically. To this end, we investigate how the self-organizing thermoregulatory huddling behaviours displayed by many species of mammals might influence natural selection of the genetic components of metabolism. By applying a simple evolutionary algorithm to a well-established model of the interactions between environmental, morphological, physiological and behavioural components of thermoregulation, we arrive at a clear, but counterintuitive, prediction: rodents that are able to huddle together in cold environments should evolve a lower thermal conductance at a faster rate than animals reared in isolation. The model therefore explains how evolution can be accelerated as a consequence of relaxed selection, and it predicts how the effect may be exaggerated by an increase in the litter size, i.e. by an increase in the capacity to use huddling behaviours for thermoregulation. Confirmation of these predictions in future experiments with rodents would constitute strong evidence of a mechanism by which self-organization can guide natural selection.

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A Minimal Model of the Phase Transition into Thermoregulatory Huddling

Glancy

Groß

Wilson

2013

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Supplementary material from "How self-organization can guide evolution"

Glancy¹,

James²,

Stuart³

2016

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Code required to run the simulations and reproduce the Figures has been uploaded as part of the supplementary material.S2. Analysis of the data in Python. After compiling S1, this script can be launched from the same directory to re-generate Figure 1 and Figure 2 from the main text (uses NumPy and matplotlib libraries). from How self-organization can guide evolution

Glancy¹,

James²,

Stuart³

2016

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Jonathan Glancy

A Self-Organising Model of Thermoregulatory Huddling

How self-organization can guide evolution

A Minimal Model of the Phase Transition into Thermoregulatory Huddling

Supplementary material from "How self-organization can guide evolution"

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