Chaos, Complexity and Transport Proceedings of the Cct 2011.
The main goal is to offer readers a panorama of recent progress in nonlinear physics, complexity and transport with attractive chapters readable by a broad audience. It allows readers to gain an insight into these active fields of research and notably promotes the interdisciplinary studies from math...
Clasificación: | Libro Electrónico |
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Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
World Scientific Pub Co Inc
2012.
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Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Preface; CONTENTS; Part A Classical Hamiltonian Dynamics; Resonant interaction of charged particles with electromagnetic waves A. A. Vasiliev, A. V. Artemyev, A. I. Neishtadt, D. L. Vainchtein and L. M. Zelenyi; 1. Introduction; 2. Main equations; 3. Single wave (non-relativistic case); 3.1. Normal propagation; 3.2. Oblique propagation; 4. Effects of the second wave; 4.1. Parallel propagation; 4.2. Nonparallel propagation; 5. Relativistic case; 6. Discussion and conclusions; Acknowledgments; References
- Superrelativistic charged particles acceleration by electromagnetic waves: Self-consistent model A. V. Artemyev, L. M. Zelenyi, and V. L. Krasovsky1. Introduction; 2. Wave-particle interaction; 3. Self-consistent approach; 4. Discussion and conclusions; Acknowledgments; References; Control of atomic transport using autoresonance D. V. Makarov, M. Yu. Uleysky and S. V. Prants; 1. Introduction; 2. Basic equations; 3. Classical dynamics; 4. Numerical simulation; 4.1. Classical autoresonance; 4.2. Quantum autoresonance; 5. Conclusion; Acknowledgments; References
- Lagrangian tools to monitor chaotic transport and mixing in the ocean S. V. Prants, M. V. Budyansky and M. Yu. Uleysky1. Introduction; 2. Lagrangian and dynamical systems methods to study transport and mixing in the ocean; 3. Transport and mixing in marine bays; 4. Transport and mixing in the Kuroshio Extension region; 5. Conclusion; References; Stochastic treatment of finite-N fluctuations in the approach towards equilibrium for mean field models W. Ettoumi and M.-C. Firpo; 1. Introduction; 2. General framework; 2.1. N-body Hamiltonian
- 2.2. From Kramers-Moyal expansion to the Fokker-Planck equation3. Quasistationary states; 3.1. Botzmann-Gibbs expectations; 3.2. How to recognize QSSs?; 3.3. Large-time disintegration of QSSs; 4. Stochastic hypothesis; 5. A practical example: The Hamiltonian Mean Field model; 5.1. Averaging the Fokker-Planck equation; 5.2. Destruction of the inner structure; 6. Conclusion; References; Anomalous transport and phase space structures B. Meziani, O. Ourrad and X. Leoncini; 1. Introduction; 2. Motion in two waves; 3. Decay of particles into islands of stability; 4. Conclusion; Acknowledgements