In 1982, R. Hamilton introduced a nonlinear evolution equation for Riemannian metrics with the aim of finding canonical metrics on manifolds. This evolution equation is known as the Ricci flow, and it has since been used widely and with great success, most notably in Perelman's solution of the Poincaré conjecture. Furthermore, various convergence theorems have been established.

This book provides a concise introduction to the subject as well as a comprehensive account of the convergence theory for the Ricci flow. The proofs rely mostly on maximum principle arguments. Special emphasis is placed on preserved curvature conditions, such as positive isotropic curvature. One of the major consequences of this theory is the Differentiable Sphere Theorem: a compact Riemannian manifold whose sectional curvatures all lie in the interval (1,4] is diffeomorphic to a spherical space form. This question has a long history, dating back to a seminal paper by H. E. Rauch in 1951, and it was resolved in 2007 by the author and Richard Schoen.

This text originated from graduate courses given at ETH Zürich and Stanford University, and is directed at graduate students and researchers. The reader is assumed to be familiar with basic Riemannian geometry, but no previous knowledge of Ricci flow is required.

Readership

Graduate students and research mathematicians interested in differential geometry and topology of manifolds.

Table of Contents

• A survey of sphere theorems in geometry
• Hamilton's Ricci flow
• Interior estimates
• Ricci flow on $S^2$
• Pointwise curvature estimates
• Curvature pinching in dimension 3
• Preserved curvature conditions in higher dimensions
• Convergence results in higher dimensions
• Rigidity results
• Convergence of evolving metrics
• Results from complex linear algebra
• Problems
• Bibliography
• Index