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Complex analysis --- Monge-Ampère equations --- Pluripotential theory. --- Monge-Ampère, Équations de --- Pluripotentiel, Théorie du --- Monge-Ampère equations --- Pluripotential theory --- Equations, Monge-Ampère --- Differential equations, Partial --- Nonlinear theories --- Potential theory (Mathematics) --- Monge-Ampère, Équations de. --- Pluripotentiel, Théorie du.

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Differential geometry. Global analysis --- Riemannian manifolds --- Monge-Ampère equations --- Riemann, Variétés de --- Monge-Ampère, Equations de --- Monge-Ampère equations --- Monge-Ampere equations --- Manifolds, Riemannian --- Riemannian space --- Space, Riemannian --- Geometry, Differential --- Manifolds (Mathematics) --- Equations, Monge-Ampère --- Differential equations, Partial --- Riemann, Variétés de --- Monge-Ampère, Equations de

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The purpose of these lecture notes is to provide an introduction to the theory of complex Monge–Ampère operators (definition, regularity issues, geometric properties of solutions, approximation) on compact Kähler manifolds (with or without boundary). These operators are of central use in several fundamental problems of complex differential geometry (Kähler–Einstein equation, uniqueness of constant scalar curvature metrics), complex analysis and dynamics. The topics covered include, the Dirichlet problem (after Bedford–Taylor), Monge–Ampère foliations and laminated currents, polynomial hulls and Perron envelopes with no analytic structure, a self-contained presentation of Krylov regularity results, a modernized proof of the Calabi–Yau theorem (after Yau and Kolodziej), an introduction to infinite dimensional riemannian geometry, geometric structures on spaces of Kähler metrics (after Mabuchi, Semmes and Donaldson), generalizations of the regularity theory of Caffarelli–Kohn–Nirenberg–Spruck (after Guan, Chen and Blocki) and Bergman approximation of geodesics (after Phong–Sturm and Berndtsson). Each chapter can be read independently and is based on a series of lectures by R. Berman, Z. Blocki, S. Boucksom, F. Delarue, R. Dujardin, B. Kolev and A. Zeriahi, delivered to non-experts. The book is thus addressed to any mathematician with some interest in one of the following fields, complex differential geometry, complex analysis, complex dynamics, fully non-linear PDE's and stochastic analysis.

Monge-Ampáere equations --- Geodesics (Mathematics) --- Kèahlerian structures --- Mathematics --- Physical Sciences & Mathematics --- Geometry --- Mathematical Theory --- Calculus --- Monge-Ampère equations. --- Kählerian structures. --- Structures, Kählerian --- Equations, Monge-Ampère --- Mathematics. --- Algebraic geometry. --- Partial differential equations. --- Functions of complex variables. --- Differential geometry. --- Several Complex Variables and Analytic Spaces. --- Differential Geometry. --- Partial Differential Equations. --- Algebraic Geometry. --- Differential geometry --- Complex variables --- Elliptic functions --- Functions of real variables --- Partial differential equations --- Algebraic geometry --- Math --- Science --- Complex manifolds --- Geometry, Differential --- Hermitian structures --- Global analysis (Mathematics) --- Differential equations, Partial --- Differential equations, partial. --- Global differential geometry. --- Geometry, algebraic. --- Monge-Ampere equations. --- Kahlerian structures.