# A universal route to pattern formation

**Authors:** Malbor Asllani, Timoteo Carletti, Duccio Fanelli, Philip K. Maini

arXiv: 1906.05946 · 2019-06-17

## TL;DR

This paper introduces a new framework for pattern formation that overcomes the limitations of Turing's classical theory, allowing for pattern emergence in systems with any diffusion ratio and many cells, applicable across various natural systems.

## Contribution

The authors propose a novel, more general mechanism for pattern formation that does not require large diffusion constant ratios, expanding the applicability of self-organization models.

## Key findings

- Patterns can emerge with any diffusivity ratio.
- Pattern formation is possible in systems with sufficiently many cells.
- Resulting patterns are robust and can be oscillatory or steady-state.

## Abstract

Self-organization, the ability of a system of microscopically interacting entities to shape macroscopically ordered structures, is ubiquitous in Nature. Spatio-temporal patterns are abundantly observed in a large plethora of applications, encompassing different fields and scales. Examples of emerging patterns are the spots and stripes on the coat or skin of animals, the spatial distribution of vegetation in arid areas, the organization of the colonies of insects in host-parasitoid systems and the architecture of large complex ecosystems. Spatial self-organization can be described following the visionary intuition of Alan Turing, who showed how non-linear interactions between slow diffusing activators and fast diffusing inhibitors could induce patterns. The Turing instability, as the mechanism described is universally referred to, was raised to paradigm status in those realms of investigations where microscopic entities are subject to diffusion, from small biological systems to large ecosystems. Requiring a significant ratio of the assigned diffusion constants however is a stringent constraint, which limited the applicability of the theory. Building on the observation that spatial interactions are usually direction biased, and often strongly asymmetric, we here propose a novel framework for the generation of short wavelength patterns which overcomes the limitation inherent in the Turing formulation. In particular, we will prove that patterns can always set in when the system is composed by sufficiently many cells - the units of spatial patchiness - and for virtually any ratio of the diffusivities involved. Macroscopic patterns that follow the onset of the instability are robust and show oscillatory or steady-state behavior.

## Full text

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## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/1906.05946/full.md

## References

27 references — full list in the complete paper: https://tomesphere.com/paper/1906.05946/full.md

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Source: https://tomesphere.com/paper/1906.05946