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1. Topological Concepts in Gauge Theories

   In these lecture notes, an introduction to topological concepts and methods in studies of gauge field theories is presented. The three paradigms of...

   F. Lenz in Topology and Geometry in Physics

   Chapter
   

2. Method of Invariant Grids

   The method of invariant grids is developed for a grid-based computation of invariant manifolds.

   Alexander N. Gorban, Ilya V. Karlin in Invariant Manifolds for Physical and Chemical Kinetics

   Chapter
   

3. Mathematical Notation and Some Terminology

   – The operator L from space W to space E: L : W → E

   Alexander N. Gorban, Ilya V. Karlin in Invariant Manifolds for Physical and Chemical Kinetics

   Chapter
   

4. References

   Alexander N. Gorban, Ilya V. Karlin in Invariant Manifolds for Physical and Chemical Kinetics

   Chapter
   

5. Invariance Equation in Differential Form

   Definition of invariance in terms of motions and trajectories assumes, at least, existence and uniqueness theorems for solutions of the original...

   Alexander N. Gorban, Ilya V. Karlin in Invariant Manifolds for Physical and Chemical Kinetics

   Chapter
   

6. Entropy, Quasiequilibrium, and Projectors Field

   Projection operators Py contribute both to the invariance equation (3.2), and to the film extension of the dynamics (4.5). Limiting results, exact...

   Alexander N. Gorban, Ilya V. Karlin in Invariant Manifolds for Physical and Chemical Kinetics

   Chapter
   

7. Chiral Anomalies and Topology

   When a field theory has a symmetry, global or local like in gauge theories, in the tree or classical approximation formal manipulations lead to...

   J. Zinn-Justin in Topology and Geometry in Physics

   Chapter
   

8. Computer Simulations of the Electric Double Layer

   We describe the Lekner–Sperb summation technique used to calculate the Coulomb interaction in 2D periodic systems, and discuss in detail the methods...

   André G. Moreira, Roland R. Netz in Novel Methods in Soft Matter Simulations

   Chapter
   

9. Molecular Dynamics of Complex Systems: Non-Hamiltonian, Constrained, Quantum-Classical

   A theoretically sound and computationally tractable treatment for non-Hamiltonian molecular dynamics is needed for simulations of complex systems....

   Giovanni Ciccotti, Galina Kalibaeva in Novel Methods in Soft Matter Simulations

   Chapter
   

10. Nonlinear superposition formulae of integrable partial differential equations by the singular manifold method

    We study by the singular manifold method a few 1+1-dimensional partial differential equations which possess N-soliton solutions for arbitrary N, i.e....

    Micheline Musette in Direct and Inverse Methods in Nonlinear Evolution Equations

    Chapter
    

11. Reverse Non-equilibrium Molecular Dynamics

    We review non-equilibrium methods for calculating transport coefficients with emphasis on the reverse non-equilibrium molecular dynamics (RNEMD)...

    Florian Müller-Plathe, Patrice Bordat in Novel Methods in Soft Matter Simulations

    Chapter
    

12. Mesoscopic Multi-particle Collision Model for Fluid Flow and Molecular Dynamics

    Several aspects of modeling dynamics at the mesoscale level are discussed: (1) The construction of a mesoscopic description of fluid dynamics. The...

    Anatoly Malevanets, Raymond Kapral in Novel Methods in Soft Matter Simulations

    Chapter
    

13. On the Reduction of Molecular Degrees of Freedom in Computer Simulations

    Molecular simulations, based on atomistic force fields are a standard theoretical tool in materials, polymers and biosciences. While various methods,...

    Alexander P. Lyubartsev, Aatto Laaksonen in Novel Methods in Soft Matter Simulations

    Chapter
    

14. Lattice Boltzmann Modeling of Complex Fluids: Colloidal Suspensions and Fluid Mixtures

    The study of complex fluid dynamics requires development of numerical tools that capture the essentials of the dynamic coupling among the different...

    Ignacio Pagonabarraga in Novel Methods in Soft Matter Simulations

    Chapter
    

15. Sato Theory and Transformation Groups. A Unified Approach to Integrable Systems

    More than 20 years ago, it was discovered that the solutions of the Kadomtsev-Petviashvili (KP) hierarchy constitute an infinite-dimensional...

    Ralph Willox, Junkichi Satsuma in Discrete Integrable Systems

    Chapter
    

16. Discrete Painlevé Equations: A Review

    We present a review of what is current knowledge about discrete Painlevé equations. We start with a historical introduction which explains how the...

    B. Grammaticos, A. Ramani in Discrete Integrable Systems

    Chapter
    

17. Nonlinear Waves, Solitons, and IST

    These lectures are written for a wide audience with diverse backgrounds. The subject is approached from a general perspective and overly detailed...

    M.J. Ablowitz in Integrability of Nonlinear Systems

    Chapter
    

18. Integrability – and How to Detect It

    We present a physicist’s approach to integrability and its detection. Starting from specific examples we present a working definition of what is...

    B. Grammaticos, A. Ramani in Integrability of Nonlinear Systems

    Chapter
    

19. Bilinear Formalism in Soliton Theory

    A brief survey of the bilinear formalism discovered by Hirota is given. First, the procedure to obtain soliton solutions of nonlinear evolution...

    J. Satsuma in Integrability of Nonlinear Systems

    Chapter
    

20. 5 Galilei Invariant Elementary Particles

    In this chapter we apply the general theory of symmetry actions as developed in Chaps. 2 and 3 to the Galilei groups of Chap. 4 splitting the...

    Gianni Cassinelli, Ernesto De Vito, ... Alberto Levrero in The Theory of Symmetry Actions in Quantum Mechanics

    Chapter