Symmetric interacting particle systems: Self-duality and hydrodynamics in dynamic random environment

Federico Sau

doi:10.4233/uuid:a0b4bc54-ec9b-4eb7-92d2-6a751993e5d9

Symmetric interacting particle systems: Self-duality and hydrodynamics in dynamic random environment

Federico Sau

Applied Probability

Research output: Thesis › Dissertation (TU Delft)

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Abstract

In this thesis, we study scaling and detailed properties of a class of conservative interacting particle systems. In particular, in the first part we derive the hydrodynamic equation for the symmetric exclusion process in presence of dynamic random environment. The second part of the thesis focuses on a detailed property of conservative particle systems and, more generally, of Markov processes, called duality. There, we study and characterize duality and self-duality relations for so-called symmetric interacting particle systems.

Original language	English
Qualification	Doctor of Philosophy
Awarding Institution	Delft University of Technology
Supervisors/Advisors	Redig, F.H.J., Supervisor
Award date	30 Sept 2019
DOIs	https://doi.org/10.4233/uuid:a0b4bc54-ec9b-4eb7-92d2-6a751993e5d9
Publication status	Published - 2019

Keywords

Interacting particle systems
Duality
Markov processes
Hydrodynamics
Random walks

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PhDthesis_SauFinal published version, 1.61 MB

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title = "Symmetric interacting particle systems: Self-duality and hydrodynamics in dynamic random environment",

abstract = "In this thesis, we study scaling and detailed properties of a class of conservative interacting particle systems. In particular, in the first part we derive the hydrodynamic equation for the symmetric exclusion process in presence of dynamic random environment. The second part of the thesis focuses on a detailed property of conservative particle systems and, more generally, of Markov processes, called duality. There, we study and characterize duality and self-duality relations for so-called symmetric interacting particle systems.",

keywords = "Interacting particle systems, Duality, Markov processes, Hydrodynamics, Random walks",

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language = "English",

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T1 - Symmetric interacting particle systems

T2 - Self-duality and hydrodynamics in dynamic random environment

AU - Sau, Federico

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N2 - In this thesis, we study scaling and detailed properties of a class of conservative interacting particle systems. In particular, in the first part we derive the hydrodynamic equation for the symmetric exclusion process in presence of dynamic random environment. The second part of the thesis focuses on a detailed property of conservative particle systems and, more generally, of Markov processes, called duality. There, we study and characterize duality and self-duality relations for so-called symmetric interacting particle systems.

AB - In this thesis, we study scaling and detailed properties of a class of conservative interacting particle systems. In particular, in the first part we derive the hydrodynamic equation for the symmetric exclusion process in presence of dynamic random environment. The second part of the thesis focuses on a detailed property of conservative particle systems and, more generally, of Markov processes, called duality. There, we study and characterize duality and self-duality relations for so-called symmetric interacting particle systems.

KW - Interacting particle systems

KW - Duality

KW - Markov processes

KW - Hydrodynamics

KW - Random walks

U2 - 10.4233/uuid:a0b4bc54-ec9b-4eb7-92d2-6a751993e5d9

DO - 10.4233/uuid:a0b4bc54-ec9b-4eb7-92d2-6a751993e5d9

M3 - Dissertation (TU Delft)

ER -

Symmetric interacting particle systems: Self-duality and hydrodynamics in dynamic random environment

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Keywords

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