Overview
- Authors:
-
-
Sergey V. Prants
-
Pacific Oceanological Institute of the Russian Academy of Sciences, Laboratory of Nonlinear Dynamical Systems, Vladivostok, Russia
-
Michael Yu. Uleysky
-
Pacific Oceanological Institute of the Russian Academy of Sciences, Laboratory of Nonlinear Dynamical Systems, Vladivostok, Russia
-
Maxim V. Budyansky
-
Pacific Oceanological Institute of the Russian Academy of Sciences, Laboratory of Nonlinear Dynamical Systems, Vladivostok, Russia
- Presents results on the Lagrangian study of large-scale mixing and transport in the ocean from simple examples to realistic problems
- Introduces the basic concepts from dynamical system theory, making the book accessible to those in the oceanographic community without strong mathematical backgrounds
- Describes the use of satellite and buoy data in the generation of numerical forecasting models of the ocean
- Includes supplementary material: sn.pub/extras
About this book
This book uses the Lagrangian approach, especially useful and convenient for studying large-scale transport and mixing in the ocean, to present a detailed view of ocean circulation. This approach focuses on simulations and on monitoring the trajectories of fluid particles, which are governed by advection equations. The first chapter of the book is devoted to dynamical systems theory methods, which provide the framework, methodology and key concepts for the Lagrangian approach. The book then moves on to an analysis of chaotic mixing and cross-stream transport in idealized models of oceanic meandering currents like the Gulfstream in the Atlantic, the Kuroshio in the Pacific, and Antarctic Circumpolar Current, after which the current state of physical oceanography is reviewed. The latter half of the book applies the techniques and methods already described in order to study eddies, currents, fronts and large-scale mixing and transport in the Far-Eastern seas and the north-western part of the Pacific Ocean. Finally, the book concludes with a discussion of Lagrangian simulation and monitoring of water contamination after the Fukushima disaster of 2011. The propagation of Fukushima-derived radionuclides, surface transport across the Kuroshio Extension current, and the role of mesoscale eddies in the transport of Fukushima-derived cesium isotopes in the ocean are examined, and a comparison of simulation results with actual measurements are presented.Written by some of the world leaders in the application of Lagrangian methods in oceanography, this title will be of benefit to the oceanographic community by presenting the necessary background of the Lagrangian approach in an accessible manner.
Similar content being viewed by others
Article
Open access
22 April 2022
Table of contents (9 chapters)
-
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 1-17
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 19-81
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 83-94
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 95-115
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 117-139
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 141-184
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 185-221
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages 223-256
-
- Sergey V. Prants, Michael Yu. Uleysky, Maxim V. Budyansky
Pages E1-E2
-
Back Matter
Pages 257-273
About the authors
Sergey V. Prants is the Head of the Department of Oceanic and Atmospheric Physics and Head of the Laboratory of Nonlinear Dynamical Systems of the Pacific Oceanological Institute of the Russian Academy of Sciences. His research interests comprise of nonlinear dynamical processes, Hamiltonian and dissipative chaos, self-organization, and dynamical symmetries. He's the author of five books and one hundred papers in international journals.