Bessel potential operator
A classical Bessel potential operator is a generalized convolution operator (or a pseudo-differential operator)
 |
 |
with symbol
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where 
is the Laplace operator, 
and 
are, respectively, the Fourier transform and its inverse, and 
is a generalized kernel (cf. also Kernel of an integral operator). If 
, the kernel 
is the modified Bessel function of the third kind (cf. also Bessel functions) and
 |
is an ordinary convolution of functions [a1], [a2], [a5].
The set of functions
 |
 |
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is known as the Bessel potential space.
extends to an isomorphism between the Bessel potential spaces: 
[a1], [a2], [a5], and even between more general Besov–Triebel–Lizorkin spaces 
[a6].
Now, let 
be a special Lipschitz domain. A linear operator 
is said to be a Bessel potential operator of order 
for 
(briefly written as 
) if [a3]:
i) 
is translation invariant: 
with 
, 
;
ii) there exists a continuous and invertible extension 
for all 
, 
;
iii) 
and its inverse 
preserve supports within 
: 
, provided 
and 
(here, 
stands for the closure of 
).
is said to be a Bessel potential operator for 
(briefly, 
) if 
and if it generates an additive group 
, 
, 
, 
[a3].
The following assertions are basic for Bessel potential operators.
1) For a special Lipschitz domain 
the inclusion 
holds if and only if
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is a generalized convolution, with
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being 
-multipliers (cf. also Multiplier theory) and 
[a3].
The group of 
can be generated as follows: 
for 
[a3].
2) Let 
, 
and 
be as in 1). There exists a generalized kernel 
such that 
for all 
; if 
, then 
.
If 
is another special Lipschitz domain and 
, 
, then 
for all 
[a3].
3) Let 
be as in 1). Any operator 
arranges an isomorphism 
of the Bessel potential spaces of functions vanishing at the boundary
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(the same for the 
-spaces).
4) Let 
be as in 1) and let, further, 
be the restriction and let 
be one of its right inverses, 
for 
. Then the restricted adjoint operator 
arranges an isomorphism, where 
. The isomorphism is independent of the choice of a right inverse 
(the same for the 
-spaces).
5) For all 
and any general Lipschitz domain 
(even for a manifold 
with a Lipschitz boundary) there exist pseudo-differential operators 
and 
such that 
and 
will be isomorphisms (the same for the 
- and 
-spaces). 
is independent of the choice of 
. If 
is the principal symbol of 
(cf. also Symbol of an operator), then 
will be the principal symbol of 
. 
can be chosen, among others, with principal symbols from the Hörmander class 
[a3], [a4].
6) The operators 
and 
from the above assertion can be applied to the lifting of pseudo-differential operators (i.e. to reduction of the order): if 
is a pseudo-differential operator with principal symbol 
, then 
will be an equivalent pseudo-differential operator, with principal symbol 
[a3], [a4].
References
| [a1] | N. Aronszajn, K. Smith, "Theory of Bessel potentials, Part 1" Ann. Inst. Fourier , 11 (1961) pp. 385–475 |
| [a2] | A.P. Calderón, "Lebesque spaces of differentiable functions and distributions" C.B. Morrey (ed.) , Partial Differential Equations , Amer. Math. Soc. (1961) pp. 33–49 |
| [a3] | R. Duduchava, F.-O. Speck, "Pseudo-differential operators on compact manifolds with Lipschitz boundary" Math. Nachr. , 160 (1993) pp. 149–191 |
| [a4] | R. Schneider, "Bessel potential operators for canonical Lipschitz domains" Math. Nachr. , 150 (1991) pp. 277–299 |
| [a5] | E. Stein, "Singular integrals and differentiability properties of functions" , Princeton Univ. Press (1970) |
| [a6] | H. Triebel, "Interpolation theory, function spaces, differential operators" , North-Holland (1978) |
| [a7] | R. Schneider, "Reduction of order for pseudodifferential operators on Lipschitz domains" Comm. Partial Diff. Eq. , 18 (1991) pp. 1263–1286 |
Bessel potential operator. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Bessel_potential_operator&oldid=46037