Logarithmic scaling of the collapse in the critical Keller-Segel equation

Sergey A. Dyachenko; Pavel M. Lushnikov; Natalia Vladimirova

doi:10.1088/0951-7715/26/11/3011

Logarithmic scaling of the collapse in the critical Keller-Segel equation

Sergey A. Dyachenko
, Pavel M. Lushnikov
, Natalia Vladimirova

Mathematics

University of New Mexico

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

10 Scopus citations

Abstract

A reduced Keller-Segel equation (RKSE) is a parabolic-elliptic system of partial differential equations which describes bacterial aggregation and the collapse of a self-gravitating gas of Brownian particles. We consider RKSE in two dimensions, where solution has a critical collapse (blow-up) if the total number of bacteria exceeds a critical value. We study the self-similar solutions of RKSE near the blow-up point. Near the collapse time, t = t_c, the critical collapse is characterized by the L ∝ (t_c - t) ^1/2 scaling law with logarithmic modification, where L is the spatial width of the collapsing solution. We develop an asymptotic perturbation theory for these modifications and show that the resulting scaling agrees well with numerical simulations. The quantitative comparison of the theory and simulations requires several terms of the perturbation series to be taken into account.

Original language	English
Pages (from-to)	3011-3041
Number of pages	31
Journal	Nonlinearity
Volume	26
Issue number	11
DOIs	https://doi.org/10.1088/0951-7715/26/11/3011
State	Published - Nov 2013

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title = "Logarithmic scaling of the collapse in the critical Keller-Segel equation",

abstract = "A reduced Keller-Segel equation (RKSE) is a parabolic-elliptic system of partial differential equations which describes bacterial aggregation and the collapse of a self-gravitating gas of Brownian particles. We consider RKSE in two dimensions, where solution has a critical collapse (blow-up) if the total number of bacteria exceeds a critical value. We study the self-similar solutions of RKSE near the blow-up point. Near the collapse time, t = tc, the critical collapse is characterized by the L ∝ (tc - t) 1/2 scaling law with logarithmic modification, where L is the spatial width of the collapsing solution. We develop an asymptotic perturbation theory for these modifications and show that the resulting scaling agrees well with numerical simulations. The quantitative comparison of the theory and simulations requires several terms of the perturbation series to be taken into account.",

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T1 - Logarithmic scaling of the collapse in the critical Keller-Segel equation

AU - Dyachenko, Sergey A.

AU - Lushnikov, Pavel M.

AU - Vladimirova, Natalia

PY - 2013/11

Y1 - 2013/11

N2 - A reduced Keller-Segel equation (RKSE) is a parabolic-elliptic system of partial differential equations which describes bacterial aggregation and the collapse of a self-gravitating gas of Brownian particles. We consider RKSE in two dimensions, where solution has a critical collapse (blow-up) if the total number of bacteria exceeds a critical value. We study the self-similar solutions of RKSE near the blow-up point. Near the collapse time, t = tc, the critical collapse is characterized by the L ∝ (tc - t) 1/2 scaling law with logarithmic modification, where L is the spatial width of the collapsing solution. We develop an asymptotic perturbation theory for these modifications and show that the resulting scaling agrees well with numerical simulations. The quantitative comparison of the theory and simulations requires several terms of the perturbation series to be taken into account.

AB - A reduced Keller-Segel equation (RKSE) is a parabolic-elliptic system of partial differential equations which describes bacterial aggregation and the collapse of a self-gravitating gas of Brownian particles. We consider RKSE in two dimensions, where solution has a critical collapse (blow-up) if the total number of bacteria exceeds a critical value. We study the self-similar solutions of RKSE near the blow-up point. Near the collapse time, t = tc, the critical collapse is characterized by the L ∝ (tc - t) 1/2 scaling law with logarithmic modification, where L is the spatial width of the collapsing solution. We develop an asymptotic perturbation theory for these modifications and show that the resulting scaling agrees well with numerical simulations. The quantitative comparison of the theory and simulations requires several terms of the perturbation series to be taken into account.

UR - https://www.scopus.com/pages/publications/84888114923

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DO - 10.1088/0951-7715/26/11/3011

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AN - SCOPUS:84888114923

SN - 0951-7715

VL - 26

SP - 3011

EP - 3041

JO - Nonlinearity

JF - Nonlinearity

IS - 11

ER -

Logarithmic scaling of the collapse in the critical Keller-Segel equation

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