During the last thirty years potential theory has undergone a rapid development, much of which can still only be found in the original papers. This book deals with one part of this development, and has two aims. The first is to give a comprehensive account of the close connection between analytic and probabilistic potential theory with the notion of a balayage space appearing as a natural link. The second aim is to demonstrate the fundamental importance of this concept by using it to give a straight presentation of balayage theory which in turn is then applied to the Dirichlet problem. We have considered it to be beyond the scope of this book to treat further topics such as duality, ideal boundary and integral representation, energy and Dirichlet forms. The subject matter of this book originates in the relation between classical potential theory and the theory of Brownian motion. Both theories are linked with the Laplace operator. However, the deep connection between these two theories was first revealed in the papers of S. KAKUTANI , , , M. KAC  and J. L. DO DB  during the period 1944-54: This can be expressed by the·fact that the harmonic measures which occur in the solution of the Dirichlet problem are hitting distri butions for Brownian motion or, equivalently, that the positive hyperharmonic func tions for the Laplace equation are the excessive functions of the Brownian semi group.
0. Classical Potential Theory.- 1. Harmonic and Hyperharmonic Functions.- 2. Brownian Semigroup.- 3. Excessive Functions.- I. General Preliminaries.- 1. Function Cones.- 2. Choquet Boundary.- 3. Analytic Sets and Capacitances.- 4. Laplace Transforms.- 5. Coercive Bilinear Forms.- II. Excessive Functions.- 1. Kernels.- 2. Supermedian Functions.- 3. Semigroups and Resolvents.- 4. Balayage Spaces.- 5. Continuous Potentials.- 6. Construction of Kernels.- 7. Construction of Resolvents.- 8. Construction of Semigroups.- III. Hyperharmonic Functions.- 1. Harmonic Kernels.- 2. Harmonic Structure of a Balayage Space.- 3. Convergence Properties.- 4. Minimum Principle and Sheaf Properties.- 5. Regularizations.- 6. Potentials.- 7. Absorbing and Finely Isolated Points.- 8. Harmonic Spaces.- IV. Markov Processes.- 1. Stochastic Processes.- 2. Markov Processes.- 3. Transition Functions.- 4. Modifications.- 5. Stopping Times.- 6. Strong Markov Processes.- 7. Hunt Processes.- 8. Four Equivalent Views of Potential Theory.- V. Examples.- 1. Subspaces.- 2. Strong Feller Kernels.- 3. Subordination by Convolution Semigroups.- 4. Riesz Potentials.- 5. Products.- 6. Heat Equation.- 7. Brownian Semigroups on the Infinite Dimensional Torus.- 8. Images.- 9. Further Examples.- VI. Balayage Theory.- 1. Balayage of Functions.- 2. Balayage of Measures.- 3. Probabilistic Interpretation.- 4. Base.- 5. Exceptional Sets.- 6. Essential Base.- 7. Penetration Time.- 8. Fine Support of Potentials.- 9. Fine Properties of Balayage.- 10. Convergence of Balayage Measures.- 11. Accumulation Points of Balayage Measures.- 12. Extreme Representing Measures.- VII. Dirichlet Problem.- 1. Perron Sets.- 2. Generalized Dirichlet Problem.- 3. Regular Points.- 4. Irregular Points.- 5. Simplicial Cones.- 6. Weak Dirichlet Problem.- 7. Characterization of the Generalized Solution.- 8. Fine Dirichlet Problem.- 9. Approximation.- 10. Removable Singularities.- VIII. Partial Differential Equations.- 1. Bauer Spaces.- 2. Semi-El1iptic Differential Operators.- 3. Smooth Bauer Spaces.- 4. Weak Solutions.- 5. Elliptic-Parabolic Differential Operators.- Notes.- Index of Symbols.- Guide to Standard Examples.