Nonlinear Dispersive Equations: Inverse Scattering and PDE Methods (Applied Mathematical Sciences, 209)

Preface
Acknowledgements
Contents
Acronyms
Glossary
Chapter 1 General Introduction
References
Chapter 2 Generalities and Basic Facts
2.1 Generalities on Wave Propagation
2.2 The Korteweg–de Vries Equation and its IST Formalism
2.3 Useful Concepts in IST
2.3.1 Lax pair and Miura transform
2.3.2 The AKNS systems
2.3.3 Bäcklund transforms
2.3.4 Riemann–Hilbert problems
2.4 The Gross–Pitaevskii Equation
2.4.1 Generalities on the Gross–Pitaevskii equation
2.4.2 Solitary waves
2.4.3 Stability of solitary waves
2.4.4 The long wave limit of the Gross–Pitaevskii equation
2.5 The mKdV Equation. Riemann–Hilbert Problem
2.5.1 The mKdV equation by PDE techniques. The breathers
2.5.2 The focusing mKdV equation by IST techniques
2.6 Small Dispersion Limit, Dispersive Shock Waves
2.7 The Cauchy Problem for Nonlinear Dispersive Equations
2.8 Numerical Methods
2.8.1 Spectral methods
2.8.2 Integration in time
2.8.2.1 Integrating Factor Methods
2.8.2.2 Driscoll’s composite Runge–Kutta Method
2.8.2.3 Exponential Time Differencing Methods
2.8.2.4 Splitting Methods
2.8.2.5 Implicit Runge–Kutta Scheme
References
Chapter 3 Benjamin–Ono and Intermediate LongWave Equations: Modeling, IST and PDE
3.1 Introduction
3.1.1 Presentation of the equations
3.1.2 A rigorous derivation in the sense of consistency
3.2 An Overview of the Inverse Scattering Framework for the ILW and BO Equations
3.3 Rigorous Results by PDE Methods
3.3.1 The linear group
3.3.2 An easy result
3.3.3 Global weak solutions
3.3.4 Semilinear versus quasilinear
3.3.4.1 Proof of Theorem 3.4
3.3.5 Proof of Theorem 3.5
3.3.6 Global well-posedness in L2
3.3.7 Long time dynamics
3.3.8 Solitary waves
3.3.8.1 Existence of solitons and multisolitons
3.3.9 Uniqueness of solitary waves
3.3.9.1 Stability of solitons and multisolitons
3.3.10 Another result on long time asymptotic behavior
3.3.11 Unique continuation properties
3.4 Rigorous Results on the Cauchy Problem by IST Methods
3.4.1 The BO equation
3.4.2 The ILW equation
3.5 Related Results and Conjectures
3.5.1 The modified cubic BO and ILW equations
3.5.2 The periodic case
3.5.2.1 IST methods
3.5.2.2 PDE methods
3.5.3 Zero dispersion limit
3.5.4 The soliton resolution conjecture
3.6 More on BO, ILW and Related Equations
3.6.1 Damping of solitary waves
3.6.2 Weighted spaces
3.6.3 Control
3.6.4 Initial-boundary value problems
3.6.5 Transverse stability issues
3.6.6 Modified BO and ILW equations
3.6.7 Higher-order BO and ILW
3.6.7.1 PDE methods
3.6.7.2 IST methods
3.6.8 Interaction of solitary waves
3.6.9 Benjamin–Ono with slowly varying potential
3.7 The Fractional KdV Equation. Generalities
3.8 The Fractional KdV and the Whitham Equations. Qualitative Properties
3.8.1 The different regimes of the fKdV equation
3.8.1.1 The “hyperbolic” regime −1 < a < 0 and the Whitham equation
3.8.1.2 The dispersive regime 0 < a < 1
3.8.1.3 Persistence and unique continuation properties
3.8.1.4 The periodic case
3.8.2 Higher-order extensions
References
Chapter 4 Davey–Stewartson and Related Systems
4.1 Derivation of Davey–Stewartson Systems
4.2 The Cauchy Problem Via PDE Methods
4.2.1 The elliptic-elliptic and hyperbolic-elliptic systems
4.2.2 More on the Zakharov–Schulman systems
4.2.3 The elliptic-hyperbolic systems
4.2.4 DS I-type systems by PDE methods
4.3 Solitary Waves
4.3.1 Non-existence of solitary waves
4.3.2 Solitary waves in the elliptic-elliptic case
4.4 The Three-Dimensional Case
4.5 Transverse Stability Issues
4.5.1 Line solitary waves
4.5.2 The Cauchy problem
4.5.3 Transverse stability
4.6 Further Comments on the “Non-Elliptic” Cubic Nonlinear Schrödinger Equations
4.7 DS II by Inverse Scattering Methods
4.7.1 The defocusing DS II system
4.7.2 The work of Nachman–Regev–Tataru
4.7.3 DS II focusing
4.8 DS I By Inverse Scattering Methods
4.8.1 Dromions for the DS I system
4.9 Dispersive Shocks, Semi-Classical Limit
4.9.1 Scattering approach for DS II in the semiclassical limit
4.10 Variants of the Davey–Stewartson Systems: The Ishimori Systems
4.10.1 The Ishimori systems
4.10.2 The Ishimori systems via PDE methods
4.10.3 The integrable Ishimori system
4.11 Numerics for DS II and DS II Type Systems
4.11.1 Perturbations of line solitons
4.11.2 Localized initial data for DS II
4.11.3 Blow-up for solutions to the focusing integrable DS II equation
4.11.4 Numerical scattering approaches
4.12 More on the Benney–Roskes/Zakharov–Rubenchik Systems
References
Chapter 5 Kadomtsev–Petviashvili and Related Equations
5.1 Introduction
5.2 Derivation of the KP Equations
5.2.1 The original derivation
5.2.2 KP as a water wave model
5.2.3 KP-I as the transonic limit of the Gross–Pitaevskii equation
5.2.4 Other derivations and variants
5.2.4.1 The KP approximation under a weak Coriolis forcing
5.2.4.2 Fifth-order KP equation
5.2.4.3 KP-BO and KP-ILW
5.2.4.4 Fractional KP equations
5.2.4.5 The Full Dispersion KP equations
5.2.4.6 KP-BBM type equations
5.2.4.7 KP and Davey–Stewartson
5.3 KP by PDE Methods
5.3.1 Generalities
5.3.2 An easy result
5.3.3 The linear group
5.3.4 The constraint problem
5.3.5 Semilinear versus quasilinear
5.3.6 The Cauchy problem for KP-II in low-regularity spaces
5.3.6.1 The Bourgain and other low-regularity results for KP-II
5.3.7 The KP-II equation in different geometries
5.3.7.1 Perturbations of line solitons
5.3.7.2 Initial-boundary value problem
5.3.8 A modified KP-II equation
5.3.9 The rotation modified KP-II equation
5.3.10 The KP-II equation in three space dimensions
5.3.11 More on the KP-II equation
5.3.12 Fifth-order KP equations
5.3.13 The Cauchy problem for the fractional KP equation
5.3.13.1 Dispersive estimates for the Full-Dispersion KP equation and consequences
5.3.14 The Cauchy problem for KP-I
5.3.14.1 Global weak solutions
5.3.14.2 Global well-posedness of the KP-I equation
5.3.15 The three-dimensional KP-I equation
5.3.15.1 The KP-I equation as the transonic limit of the Gross–Pitaevskii equation
5.3.16 KP-I in different geometries
5.3.17 Finite time blow-up
5.4 The Fifth-Order KP-I Equation
5.5 The KP-BBM Equations
5.6 The Dissipative KP Equations
5.7 Solitary Waves of KP Equations
5.7.1 Non-existence of traveling waves for the KP-type equations
5.7.2 Existence of solitary waves of the KP-I equation
5.7.2.1 The lump and other special solutions
5.7.2.2 Solitary waves by variational methods
5.7.3 Properties of solitary waves
5.7.3.1 Regularity
5.7.3.2 Algebraic decay of the solitary waves
5.7.3.3 Ground state solutions. Cylindrical symmetry
5.7.4 Stability of KP-I solitary waves. Finite time blow-up for generalized KP-I equations
5.7.4.1 Gross–Pitaevskii and Kadomtsev–Petviashvili: the solitary waves aspect
5.7.4.2 The 3D case: Transonic limit in 3D. Justification of the upper branch of the GP solitary waves (Chiron–Maris 2017)
5.7.4.3 Solitary waves of the rotation modified KP equation
5.7.4.4 Solitary waves of the full-dispersion Kadomtsev–Petviashvili equation
5.7.5 Transverse stability/instability of the line soliton
5.7.5.1 Linear and spectral stability
5.7.5.2 The Cauchy problem for stability issues
5.7.5.3 Transverse stability: instability problems for variant of KP equations
5.7.6 Nature of the instability. Numerical simulations
5.7.7 Varia
5.8 Control
5.9 Small Dispersion Limit
5.10 Long Time Behavior
5.10.1 Asymptotic behavior of small solutions
5.10.2 Large data long time asymptotics in the Kadomtsev–Petviashvili models
5.11 KP by Inverse Scattering Techniques
5.11.1 IST Formalism
5.11.2 Rigorous results on the Cauchy problem
5.11.2.1 The KP-II equation
5.11.2.2 The KP-I equation
5.11.3 The Cauchy problem on the background of a line soliton
5.11.4 The KP-I lump
5.11.5 Conservation laws
5.11.6 Multi-lump solutions of the KP-I equation
5.11.7 Periodic solitons of the KP-I equation
5.11.8 The line solitons of the KP-II equation
5.11.9 Genus N (Krichever) solutions
5.12 Systems of KP Equations
5.13 Final Comments
References
Chapter 6 Kadomtsev–Petviashvili and Related Equations
6.1 The Novikov–Veselov Equation
6.1.1 General facts
6.1.2 Novikov–Veselov by PDE techniques
6.1.3 Results using integrability
6.2 The Derivative Nonlinear Schrödinger Equation
6.2.1 Physical background
6.2.2 General facts and results by pure PDE techniques
6.2.3 Mixing IST and PDE techniques
6.3 Final Comments
References
Index