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Abstract
We hereby develop the theory of Turing instability for reaction-diffusion systems defined on m-directed hypergraphs, the latter being a generalization of hypergraphs where nodes forming hyperedges can be shared into two disjoint sets, the head nodes and the tail nodes. This framework encodes thus for a privileged direction for the reaction to occur: the joint action of tail nodes is a driver for the reaction involving head nodes. It thus results a natural generalization of directed networks. Based on a linear stability analysis, we have shown the existence of two Laplace matrices, allowing to analytically prove that Turing patterns, stationary or wave-like, emerge for a much broader set of parameters in the m-directed setting. In particular, directionality promotes Turing instability, otherwise absent in the symmetric case. Analytical results are compared to simulations performed by using the Brusselator model defined on a m-directed m-hyperring, as well as on a m-directed random hypergraph
Original language | English |
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Article number | 115730 |
Journal | Chaos, Solitons & Fractals |
Volume | 189 |
Issue number | 2 |
DOIs | |
Publication status | Published - 15 Nov 2024 |
Keywords
- Turing patterns
- Higher-order structures
- m-directed hypergraphs
- Hypergraphs
- Brusselator model
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Dive into the research topics of 'Impact of directionality on the emergence of Turing patterns on m-directed higher-order structures'. Together they form a unique fingerprint.Activities
- 1 Participation in conference
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International School and Conference on Network Science
Carletti, T. (Invited Speaker)
15 Jan 2025 → 17 Jan 2025Activity: Participating in or organising an event types › Participation in conference