Author: Khrennikov, Andrei
Title: Ultrametric diffusion equation on energy landscape to model disease spread in hierarchic socially clustered population Cord-id: rv34kjnm Document date: 2021_7_21
ID: rv34kjnm
Snippet: We present a new mathematical model of disease spread reflecting some specialties of the covid-19 epidemic by elevating the role of hierarchic social clustering of population. The model can be used to explain slower approaching herd immunity, e.g., in Sweden, than it was predicted by a variety of other mathematical models and was expected by epidemiologists; see graphs Fig. 1,2. The hierarchic structure of social clusters is mathematically modeled with ultrametric spaces having treelike geometry
Document: We present a new mathematical model of disease spread reflecting some specialties of the covid-19 epidemic by elevating the role of hierarchic social clustering of population. The model can be used to explain slower approaching herd immunity, e.g., in Sweden, than it was predicted by a variety of other mathematical models and was expected by epidemiologists; see graphs Fig. 1,2. The hierarchic structure of social clusters is mathematically modeled with ultrametric spaces having treelike geometry. To simplify mathematics, we consider trees with the constant number [Formula: see text] of branches leaving each vertex. Such trees are endowed with an algebraic structure, these are [Formula: see text]-adic number fields. We apply theory of the [Formula: see text]-adic diffusion equation to describe a virus spread in hierarchically clustered population. This equation has applications to statistical physics and microbiology for modeling dynamics on energy landscapes. To move from one social cluster (valley) to another, a virus (its carrier) should cross a social barrier between them. The magnitude of a barrier depends on the number of social hierarchy’s levels composing this barrier. We consider linearly increasing barriers. A virus spreads rather easily inside a social cluster (say working collective), but jumps to other clusters are constrained by social barriers. This behavior matches with the covid-19 epidemic, with its cluster spreading structure. Our model differs crucially from the standard mathematical models of spread of disease, such as the SIR-model; in particular, by notion of the probability to be infected (at time [Formula: see text] in a social cluster [Formula: see text]). We present socio-medical specialties of the covid-19 epidemic supporting our model.
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