Impact of diffusion on synchronization pattern of epidemics in non-identical meta-population networks

Anika Roy; Ujjwal Shekhar; Aditi Bose; Subrata Ghosh; Santosh Nannuru; Syamal Kumar Dana; Chittaranjan Hens

doi:10.1063/5.0222358

Impact of diffusion on synchronization pattern of epidemics in non-identical meta-population networks

Anika Roy, Ujjwal Shekhar, Aditi Bose, Subrata Ghosh, Santosh Nannuru, Syamal Kumar Dana, Chittaranjan Hens

Research output: Contribution to journal › Article › peer-review

Abstract

In epidemic networks, it has been demonstrated that implementing any intervention strategy on nodes with specific characteristics (such as a high degree or node betweenness) substantially diminishes the outbreak size. We extend this finding with a disease-spreading meta-population model using testkits to explore the influence of migration on infection dynamics within the distinct communities of the network. Notably, we observe that nodes equipped with testkits and no testkits tend to segregate into two separate clusters when migration is low, but above a critical migration rate, they coalesce into one single cluster. Based on this clustering phenomenon, we develop a reduced model and validate the emergent clustering behavior through comprehensive simulations. We observe this property in both homogeneous and heterogeneous networks.

Original language	English
Article number	103120
Journal	Chaos
Volume	34
Issue number	10
DOIs	https://doi.org/10.1063/5.0222358
State	Published - 1 Oct 2024
Externally published	Yes

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abstract = "In epidemic networks, it has been demonstrated that implementing any intervention strategy on nodes with specific characteristics (such as a high degree or node betweenness) substantially diminishes the outbreak size. We extend this finding with a disease-spreading meta-population model using testkits to explore the influence of migration on infection dynamics within the distinct communities of the network. Notably, we observe that nodes equipped with testkits and no testkits tend to segregate into two separate clusters when migration is low, but above a critical migration rate, they coalesce into one single cluster. Based on this clustering phenomenon, we develop a reduced model and validate the emergent clustering behavior through comprehensive simulations. We observe this property in both homogeneous and heterogeneous networks.",

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AU - Shekhar, Ujjwal

AU - Bose, Aditi

AU - Ghosh, Subrata

AU - Nannuru, Santosh

AU - Kumar Dana, Syamal

AU - Hens, Chittaranjan

PY - 2024/10/1

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Impact of diffusion on synchronization pattern of epidemics in non-identical meta-population networks

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