Confinement by biased velocity jumps: Aggregation of Escherichia Coli

Vincent Calvez; Gaël Raoul; Christian Schmeiser

doi:10.3934/krm.2015.8.651

Confinement by biased velocity jumps: Aggregation of Escherichia Coli

Vincent Calvez
, Gaël Raoul
, Christian Schmeiser

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

Abstract

We investigate a one-dimensional linear kinetic equation derived from a velocity jump process modelling bacterial chemotaxis in presence of an external chemical signal centered at the origin. We prove the existence of a positive equilibrium distribution with an exponential decay at infinity. We deduce a hypocoercivity result, namely: the solution of the Cauchy problem converges exponentially fast towards the stationary state. The strategy follows [J. Dolbeault, C. Mouhot, and C. Schmeiser, Hypocoercivity for linear kinetic equations conserving mass, Trans. AMS 2014]. The novelty here is that the equilibrium does not belong to the null spaces of the collision operator and of the transport operator. From a modelling viewpoint, it is related to the observation that exponential confinement is generated by a spatially inhomogeneous bias in the velocity jump process.

Original language	English
Pages (from-to)	651-666
Number of pages	16
Journal	Kinetic and Related Models
Volume	8
Issue number	4
DOIs	https://doi.org/10.3934/krm.2015.8.651
Publication status	Published - 1 Jan 2015

Keywords

Chemotaxis
Equilibrium
Kinetic equations
Velocity-jump processes
hypocoercivity

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10.3934/krm.2015.8.651

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@article{05642bd124804c6297f401718fe65080,

title = "Confinement by biased velocity jumps: Aggregation of Escherichia Coli",

abstract = "We investigate a one-dimensional linear kinetic equation derived from a velocity jump process modelling bacterial chemotaxis in presence of an external chemical signal centered at the origin. We prove the existence of a positive equilibrium distribution with an exponential decay at infinity. We deduce a hypocoercivity result, namely: the solution of the Cauchy problem converges exponentially fast towards the stationary state. The strategy follows [J. Dolbeault, C. Mouhot, and C. Schmeiser, Hypocoercivity for linear kinetic equations conserving mass, Trans. AMS 2014]. The novelty here is that the equilibrium does not belong to the null spaces of the collision operator and of the transport operator. From a modelling viewpoint, it is related to the observation that exponential confinement is generated by a spatially inhomogeneous bias in the velocity jump process.",

keywords = "Chemotaxis, Equilibrium, Kinetic equations, Velocity-jump processes, hypocoercivity",

author = "Vincent Calvez and Ga{\"e}l Raoul and Christian Schmeiser",

note = "Publisher Copyright: {\textcopyright} American Institute of Mathematical Sciences.",

year = "2015",

month = jan,

day = "1",

doi = "10.3934/krm.2015.8.651",

language = "English",

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journal = "Kinetic and Related Models",

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TY - JOUR

T1 - Confinement by biased velocity jumps

T2 - Aggregation of Escherichia Coli

AU - Calvez, Vincent

AU - Raoul, Gaël

AU - Schmeiser, Christian

N1 - Publisher Copyright: © American Institute of Mathematical Sciences.

PY - 2015/1/1

Y1 - 2015/1/1

N2 - We investigate a one-dimensional linear kinetic equation derived from a velocity jump process modelling bacterial chemotaxis in presence of an external chemical signal centered at the origin. We prove the existence of a positive equilibrium distribution with an exponential decay at infinity. We deduce a hypocoercivity result, namely: the solution of the Cauchy problem converges exponentially fast towards the stationary state. The strategy follows [J. Dolbeault, C. Mouhot, and C. Schmeiser, Hypocoercivity for linear kinetic equations conserving mass, Trans. AMS 2014]. The novelty here is that the equilibrium does not belong to the null spaces of the collision operator and of the transport operator. From a modelling viewpoint, it is related to the observation that exponential confinement is generated by a spatially inhomogeneous bias in the velocity jump process.

AB - We investigate a one-dimensional linear kinetic equation derived from a velocity jump process modelling bacterial chemotaxis in presence of an external chemical signal centered at the origin. We prove the existence of a positive equilibrium distribution with an exponential decay at infinity. We deduce a hypocoercivity result, namely: the solution of the Cauchy problem converges exponentially fast towards the stationary state. The strategy follows [J. Dolbeault, C. Mouhot, and C. Schmeiser, Hypocoercivity for linear kinetic equations conserving mass, Trans. AMS 2014]. The novelty here is that the equilibrium does not belong to the null spaces of the collision operator and of the transport operator. From a modelling viewpoint, it is related to the observation that exponential confinement is generated by a spatially inhomogeneous bias in the velocity jump process.

KW - Chemotaxis

KW - Equilibrium

KW - Kinetic equations

KW - Velocity-jump processes

KW - hypocoercivity

U2 - 10.3934/krm.2015.8.651

DO - 10.3934/krm.2015.8.651

M3 - Article

AN - SCOPUS:84937398245

SN - 1937-5093

VL - 8

SP - 651

EP - 666

JO - Kinetic and Related Models

JF - Kinetic and Related Models

IS - 4

ER -

Confinement by biased velocity jumps: Aggregation of Escherichia Coli

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