Martin boundary in potential theory
The ideal boundary of a Green space 
(see also Boundary (in the theory of uniform algebras)), which allows one to construct the characteristic representation of positive harmonic functions in 
. Let 
be a locally compact, non-compact, topological space, and let 
be a family of continuous functions 
. The Constantinescu–Cornea theorem [2] asserts that, up to a homeomorphism, there is a unique compact space 
with the following properties: 1) 
is an everywhere-dense subspace of 
; 2) each 
extends continuously to a function 
on 
, separating points on the ideal boundary 
of 
relative to 
; and 3) 
is an open set in 
.
Now, let 
be a bounded domain in a Euclidean space 
, 
, or, more generally, a Green space; let 
be the Green function on 
with pole 
and let 
be fixed. The Martin space or Martin compactification 
of 
is obtained via the Constantinescu–Cornea theorem by taking for 
the family
 |
where, by definition, 
. The Martin boundary is the corresponding ideal boundary 
. The Martin topology 
is the topology on the Martin space 
. Two Martin spaces 
, 
corresponding to different points 
are homeomorphic. The function 
, the extension of 
, is harmonic in 
and jointly continuous in the variables 
; 
is a metrizable space. Martin's fundamental theorem [1] asserts: The class of all positive harmonic functions 
on 
is characterized by the Martin representation:
 | (*) |
where 
is a positive Radon measure on 
. The measure 
in (*) is not uniquely determined by the function 
. A harmonic function 
is called minimal in 
if each harmonic function 
such that 
in 
is proportional to 
. Minimal harmonic functions 
are proportional to 
, the corresponding points 
are called minimal, and the set of minimal points 
is called the minimal Martin boundary. If one poses the additional condition that 
in (*) be concentrated on 
, one obtains the canonical Martin representation:
 |
in which the measure 
is uniquely determined by 
.
Examples. a) If 
is a ball of radius 
in 
, 
, then
 |
is the Poisson kernel, 
is the Euclidean closure 
, the Martin boundary 
is the sphere 
, all points of which are minimal. The representation (*) in this case reduces to the Poisson–Herglotz formula (see Integral representation of an analytic function; Poisson integral).
b) The Martin boundary 
coincides with the Euclidean boundary 
whenever 
is a sufficiently smooth hypersurface in 
, 
.
c) If 
is a simply-connected domain in the plane, then the Martin boundary 
coincides with the set of limit elements, or Carathéodory prime ends. Thus, an element of the Martin boundary 
can be considered as a generalization of the notion of a prime end to dimension 
.
References
| [1] | R.S. Martin, "Minimal positive harmonic functions" Trans. Amer. Math. Soc. , 49 (1941) pp. 137–172 |
| [2] | C. Constantinescu, A. Cornea, "Ideale Ränder Riemannscher Flächen" , Springer pp. 1963 |
| [3] | M. Brelot, "On topologies and boundaries in potential theory" , Springer (1971) |
Comments
See also [a1], Chapt. 12, for a concise treatment. For Martin boundaries for the heat equation or in probabilistic potential theory, see [a3].
References
| [a1] | M. Brélot, "Eléments de la théorie classique du potentiel" , Sorbonne Univ. Centre Doc. Univ. , Paris (1959) |
| [a2] | M. Brelot, "Axiomatique des fonctions harmoniques" , Univ. Montréal (1966) |
| [a3] | J.L. Doob, "Classical potential theory and its probabilistic counterpart" , Springer (1984) pp. 390 |
Martin boundary in potential theory. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Martin_boundary_in_potential_theory&oldid=14144