Riesz potential
-potential
A potential of the form
 |
where 
is a positive Borel measure of compact support on the Euclidean space 
, 
, and 
is the distance between the points 
. When 
and 
, the Riesz potential coincides with the classical Newton potential; when 
and 
, the limit case of the Riesz potential is in some sense the logarithmic potential. When 
and 
, the Riesz potential is a superharmonic function on the entire space 
; moreover, in the classical case 
, outside the support 
of 
, the potential 
is a harmonic function. When 
, the Riesz potential 
is a subharmonic function outside 
. For all 
the Riesz potential 
is a lower semi-continuous function on 
, continuous outside 
.
Among the general properties of Riesz potentials the following are the most important. The continuity principle: If 
and if the restriction 
is continuous at the point 
, then 
is continuous at 
as a function on 
. The restricted maximum principle: If 
, then 
everywhere on 
. When 
, a more precise maximum principle is valid: If 
, then 
everywhere on 
(this statement remains valid also when 
and 
, that is, for the logarithmic potential).
The capacity theory for Riesz potentials can be constructed, for example, on the basis of the concept of the 
-energy of a measures 
:
 |
One may assume that for a compact set 
,
 |
where the infimum is taken over all measures 
concentrated on 
and such that 
; then the 
-capacity is equal to
 |
If 
, then the infimum is attained on the capacitary measure 
(also called equilibrium measure), which is concentrated on 
, 
, generating the corresponding capacitary 
-potential 
(cf. also Capacity potential). The further construction of 
-capacities of arbitrary sets is carried out in the same way as for the classical capacities.
The Riesz potential is called after M. Riesz (see [2]), who obtained a number of important properties of Riesz potentials; for the first time such potentials were studied by O. Frostman (see [1]).
References
| [1] | O. Frostman, "Potentiel d'equilibre et capacité des ensembles avec quelques applications à la théorie des fonctions" Medd. Lunds Univ. Mat. Sem. , 3 (1935) pp. 1–118 |
| [2] | M. Riesz, "Intégrales de Riemann–Liouville et potentiels" Acata Sci. Math. Szeged , 9 (1938) pp. 1–42 |
| [3] | N.S. Landkof, "Foundations of modern potential theory" , Springer (1972) (Translated from Russian) |
| [4] | W.K. Hayman, P.B. Kennedy, "Subharmonic functions" , 1 , Acad. Press (1976) |
Comments
For 
even and 
, 
is a fundamental solution of the polyharmonic equation 
, otherwise 
is a fundamental solution. Riesz potentials are used in the theory of elliptic differential equations of order 
, see [a2]. A treatment of Riesz potentials in the framework of balayage spaces is given in [a1].
The Riesz kernels 
are the standard examples of convolution kernels. Thus, Riesz potentials may be regarded as special singular integrals. For more details on this interesting point of view see [a3].
References
| [a1] | J. Bliedtner, W. Hansen, "Potential theory. An analytic and probabilistic approach to balayage" , Springer (1986) |
| [a2] | B.W. Schulze, G. Wildenhain, "Methoden der Potentialtheorie für elliptische Differentialgleichungen beliebiger Ordnung" , Birkhäuser (1977) |
| [a3] | E.M. Stein, "Singular integrals and differentiability properties of functions" , Princeton Univ. Press (1970) |
| [a4] | L. Carleson, "Selected problems on exceptional sets" , v. Nostrand (1967) |
Riesz potential. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Riesz_potential&oldid=48566