Hodge Theory and Complex Algebraic Geometry II: Volume 2

The second of two volumes offering a modern account of Kaehlerian geometry and Hodge theory for researchers in algebraic and differential geometry.

Claire Voisin (Author), Leila Schneps (Translated by)

9780521802833, Cambridge University Press

Hardback, published 3 July 2003

364 pages, 4 b/w illus. 22 exercises
22.9 x 2.4 x 15.2 cm, 0.7 kg

Prize Winner Cambridge University Press congratulates Claire Voisin, winner of the 2007 Ruth Lyttle Satter Prize in Mathematics!

The 2003 second volume of this account of Kaehlerian geometry and Hodge theory starts with the topology of families of algebraic varieties. Proofs of the Lefschetz theorem on hyperplane sections, the Picard–Lefschetz study of Lefschetz pencils, and Deligne theorems on the degeneration of the Leray spectral sequence and the global invariant cycles follow. The main results of the second part are the generalized Noether–Lefschetz theorems, the generic triviality of the Abel–Jacobi maps, and most importantly Nori's connectivity theorem, which generalizes the above. The last part of the book is devoted to the relationships between Hodge theory and algebraic cycles. The book concludes with the example of cycles on abelian varieties, where some results of Bloch and Beauville, for example, are expounded. The text is complemented by exercises giving useful results in complex algebraic geometry. It will be welcomed by researchers in both algebraic and differential geometry.

Introduction. Part I. The Topology of Algebraic Varieties: 1. The Lefschetz theorem on hyperplane sections
2. Lefschetz pencils
3. Monodromy
4. The Leray spectral sequence
Part II. Variations of Hodge Structure: 5. Transversality and applications
6. Hodge filtration of hypersurfaces
7. Normal functions and infinitesimal invariants
8. Nori's work
Part III. Algebraic Cycles: 9. Chow groups
10. Mumford' theorem and its generalisations
11. The Bloch conjecture and its generalisations
References
Index.

Subject Areas: Algebraic topology [PBPD], Algebraic geometry [PBMW]