
This textbook is designed to give graduate students an understanding of integrable systems via the study of Riemann surfaces, loop groups, and twistors. The book has its origins in a series of lecture courses given by the authors, all of whom are internationally known mathematicians and renowned expositors. It is written in an accessible and informal style, and fills a gap in the existing literature. The introduction by Nigel Hitchin addresses the meaning of integrability: how do we recognize an integrable system? His own contribution then develops connections with algebraic geometry, and includes an introduction to Riemann surfaces, sheaves, and line bundles. Graeme Segal takes the Korteweg de Vries and nonlinear Schrödinger equations as central examples, and explores the mathematical structures underlying the inverse scattering transform. He explains the roles of loop groups, the Grassmannian, and algebraic curves. In the final part of the book, Richard Ward explores the connection between integrability and the self-dual Yang-Mills equations, and describes the correspondence between solutions to integrable equations and holomorphic vector bundles over twistor space.
This text investigates the mathematical foundations of integrable systems by synthesizing the disparate fields of twistors, loop groups, and Riemann surfaces. The authors, all distinguished mathematicians, utilize their collective expertise to bridge the gap between abstract algebraic geometry and the practical study of nonlinear partial differential equations. By presenting a unified framework, the book provides a structured approach for graduate students to identify and analyze integrable systems across various physical and mathematical contexts.
What You Will Find
Scope Limits
Experts recognize this work as a foundational resource for students transitioning into research-level mathematical physics. Readers frequently note the high level of technical rigor, though they appreciate the authors' ability to maintain clarity throughout complex derivations.
Page Count:
147
Publication Date:
2013-01-01
Publisher:
Oxford University Press
ISBN-10:
0191664456
ISBN-13:
9780191664458
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