1 / 38

Twisted Kähler -Einstein C urrents and Relative Pluricanonical Systems

This presentation discusses the construction of canonical singular Hermitian metrics on the canonical bundle of varieties, emphasizing the requirements for plurisubharmonic behavior and semi-positive curvature in projective families. We explore the Monge-Ampère foliation defined by such metrics and the existence of twisted Kähler-Einstein currents. The results leverage complex Monge-Ampère equations, the variation of Hodge structures, and techniques in relative geometry to establish smoothness and regularity conditions, offering insights into the dynamical systems of Bergman kernels.

sumi
Download Presentation

Twisted Kähler -Einstein C urrents and Relative Pluricanonical Systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Twisted Kähler-Einstein CurrentsandRelative Pluricanonical Systems Hajime TSUJI Sophia Univesity Durhan July 2 , 2012

  2. Main Result

  3. Scheme of the proof

  4. Canonical metrics • Construct a canonical singular hermitian metrics on the canonical bundle of the varieties. • Requirement : The metrics varies in a plurisubharmonicway,i.e. the metrics has semipositive curvature on projective families(hopefully also for Kähler families). • The metrics defines the Monge-Ampère foliation on the family.

  5. Kähler-Einstein metrics Kähler-Einstein Theorem (Aubin-Yau)

  6. Canonical ring We want to construct a (singular) Kähler metric which reflects the canonical ring.

  7. Iitakafibration Iitakafibration is the most naïve geometric realization of the positivity of the canonical ring.

  8. Iiakafibration 2

  9. HodgeQ-line bundle

  10. Hodge metric By the variation of Hodge structure we have :

  11. Fig.1

  12. TwistedKähler-Einstein currents

  13. Existence of Twisted Kähler-Einstein currents And let Let be a KLT pair with Theorem . And let be the Iitakafibration of be the Hodge line bundle with the Hodge metric. Then there exists a unique twisted Kähler-Einstein current on

  14. Monge Ampère equation Complex Monge-Ampère equation

  15. Monge-Ampère equations on compactKähler manifolds

  16. Relative Iitakafibrations

  17. Relative Twisted Kähler-Einstein currents

  18. Relative Twisted Kähler-Einstein currents 2

  19. Variation of Twisted Kähler-Einstein currents Theorem

  20. Dynamical system of Bergman kernels Approximate in terms of Bergman kernels.

  21. Monge-Ampère equations and Bergman kernels

  22. Berndtsson’s theorem(with Păun)

  23. Use of the Plurisubharmonicity of Bergman kernels

  24. Dirichlet problem for complex Monge-Ampère equations We consider the Dirichlet problem:

  25. Boudary regularity

  26. Interior regularity

  27. Dirichlet construction of twisted Kähler-Einstein currentsI

  28. Dirichlet problem for complex Monge-Ampere equationsII

  29. Smoothness

  30. Proof of the smoothness (1) Construct the twisted Kähler-Eisntein current as the limit of Dirichlet problems of complex Monge-Ampère equations. (2) Consider the family of exhaustion via strongly pseudoconvex domains and apply the implicit function theorem to the solution of complex Monge-Ampère equations. (3) Apply the weighted uniform estimates to the solution and taking the limit for the horizontal derivatives.

  31. Monge-Ampère foliations

  32. Descent of leaves

  33. Use of the weak semistability

  34. Flatness of the relative canonical systems along leaves

  35. Isometries

  36. Closedness of the leaves

  37. Decent of the positivity

  38. Positivity of the determinant

More Related