1. Introduction
The paper deals with local and nonlocal improved Hardy inequalities with a class of weights
of a quite general type and with inverse square potentials perturbed by a function
V. The paper fits into the context of Hardy type inequalities with weights stated in [
1].
Hardy’s inequality was introduced in 1920 [
2] in the one-dimensional case (see also [
3,
4]). The classical Hardy inequality in
is (see, e.g., [
5,
6,
7] for historical reviews, and [
8])
for any functions
, where
is the optimal constant.
Weighted Hardy inequalities with an optimal constant depending on a weight function
have been stated in [
9,
10] with Gaussian measures and inverse square potentials with a single pole and in the multipolar case, respectively. In a setting of more general measures, we refer to [
11,
12,
13,
14], in the last papers with multipolar potentials.
In particular, in [
12], the authors proved the inequality
for any functions
in a weighted Sobolev space with
the optimal constant and
,
constants depending on
. For example, when
,
, it yields
and
, whereas if
,
, we get
(see [
12]).
In this paper, we improve this results by adding a nonnegative correction term in the left-hand side in (
2).
In particular, we state sufficient conditions on
V to get in
the estimate
for any functions
in a suitable Sobolev space with a weight satisfying suitable local integrability assumptions, where
and
is the constant in (
2).
The class of weight functions includes Gaussian functions and weights involving a distance to the origin.
To prove the result we use a method based on the introduction of a suitable vector-valued function and on a generalized vector field method (see [
15] for some results when the weights satisfy the Hölder condition).
Examples of weight functions are shown in the paper.
In the case of the Lebesgue measure there is a very huge literature on the extension of Hardy’s inequality. In particular, the improved version of the classical Hardy inequality in a bounded domain
in
,
,
was stated in [
16] for all
.
Later improvements of the estimate (
4) of the type
can be found, for example, in [
17,
18,
19,
20].
We obtain, using the method to get the inequality in the whole space, weighted versions of the local estimate (
5) for some functions
V, and well-known inequalities when
. In particular, we focus our attention on the inequalities
and, for
,
for any functions
, where
is the unit ball in
. For
, we get the weighted version of (
4) with 4 in place of
.
Hardy inequalities are applied in many fields. From a mathematical point of view, a motivation for us to study Hardy inequalities with a weight and related improvements is due to their applications to evolution problems
where
and
L is the Kolmogorov operator
defined on smooth functions, perturbed by singular potentials
.
An existence result can be obtained, reasoning as in [
11], following Cabré and Martel’s approach based on the relation between the weak solution of
and the estimate of the
bottom of the spectrum of the operator
which results from the Hardy inequality. In the case
, Cabré and Martel in [
21] showed that the boundedness of
was a necessary and sufficient condition for the existence of positive exponentially bounded in time solutions to the associated initial value problem. Later, in [
9,
11,
13], similar results were extended to Kolmogorov operators perturbed by inverse square potentials, and in the latter paper, in the multipolar case. The proof used some properties of the operator
L and of its corresponding semigroup in
.
In this paper, we include the existence result for the sake of completeness.
The paper is organized as follows.
In
Section 2, we introduce the class of weights and the conditions on the potentials
V with some examples. In
Section 3, we state the improved weighted Hardy inequality and some consequences.
Section 4 is devoted to the weighted local estimates. Finally, in
Section 5, we show an application of the estimates to evolution problems.
2. A Class of Weight Functions and Potentials
Let be a weight function on . We define the weighted Sobolev space as the space of functions in whose weak derivatives belong to .
The class of function is considered to fulfill the conditions
;
.
Let us observe that under the assumption
, we get
. The reason we assume
is that we need the density of the space
in
(see e.g., [
22]). Thus, we can regard
as the completion of
with respect to the Sobolev norm
We introduce in the proof of the Hardy inequality in the next section the function , with g a radial function, for suitable values of . We need the following condition on g.
;
.
The assumption on the potential V in the estimates is the following
and
where
,
are the first and second derivatives with respect to
, respectively.
Under condition
in
, we can integrate by parts in the proof of the inequality in the next section. The class of radial functions
g satisfying
in
is such that
which implies that
is decreasing, so we have
If
, this condition involves that the function
is decreasing
as we can see integrating (
10) in
,
.
Functions satisfying condition (
9) in
,
, for example, are the functions
,
,
,
.
The functions
W such that there exists a positive radial solution of the Bessel equation associated to the potential
W
are good functions. We observe that, if
, the Bessel function
is a positive solution of Equation (
11).
The author in [
19] proved that, under suitable hypotheses, Equation (
11) was a necessary and sufficient condition to get an improved Hardy inequality in bounded domains in
.
A further assumption we need is the following.
There exist constants
,
and
if
,
if
, such that
or, equivalently, such that the function
satisfies the inequality
For
g fixed, it is a condition for
. For example, if
, weight functions satisfying
are the functions
for suitable values of
m (see [
12]). Conversely, for
fixed,
represents a condition on
g.
Finally, we remark that the weights in (
13) fulfill condition
.
3. Weighted Improved Hardy Inequalities
In this section, we state a weighted improved Hardy inequality in the setting of a more general measure with respect to [
15]. This allows us to improve the results in [
12] on weighted Hardy inequalities by adding a nonnegative correction term in the estimates.
The method to get the result was introduced in [
15] for a class of weights satisfying the Hölder condition. We enlarge the class of weights for which we can state the result. For this class, a weighted Hardy inequality with a different method was stated in [
12].
The next result states sufficient conditions to get an improved Hardy inequality with weight.
Theorem 1. If – hold, then we get the estimatefor any functions . Proof. By the density result, we prove (
14) for any
.
We introduce the vector-valued function
where
,
.
Now, we observe that
,
, where
is the
jth component of
F. Indeed, for any
K compact set in
, by the Hölder and the classical Hardy inequalities, using hypotheses
in
on
and
in
on
g, we obtain the following estimate
To obtain the local integrability of the partial derivative of
we estimate the terms on the right-hand side in (
15). The terms
and
belong to
by hypotheses,
and
and
can be estimated using the Hardy inequality and the hypothesis
in
as above. As regards the remaining term, we have
Now, we start from the following integral
The first step is to estimate the integral on the left-hand side in (
16) from above. To this aim, we integrate by parts and use Hölder’s and Young’s inequalities to get
On the other hand, starting from (
16), by condition
, we obtain
The inequalities (
17) and (
18) lead us to the estimate
The maximum value of the first constant on the left-hand side in (
19) is
attained for
.
Observing that
and keeping in mind condition
, we obtain the inequality (
14). □
Remark 1. For and , we obtain a weighted Hardy inequality. For , and so , and the method to get the result in Theorem 1 reduces to the vector field method used in [8] to prove the classical Hardy inequality. An example of a weight satisfying condition
is given by the function
, for
. In this case, condition (
12) is verified for
for any
. Then, as a consequence of Theorem 1, we get the inequality
for any functions
. For
, the inequality above is the Caffarelli–Niremberg inequality.
Finally, as a direct consequence of Theorem 1, we deduce the following result concerning a class of general weighted Hardy inequalities for
V satisfying
for any functions
.
4. Local Estimates
In this section, we state some local weighted estimates by means of the method used to prove Theorem 1. These estimates represent the weighted version of well-known improved Hardy inequalities in a bounded subset of
(see [
17,
18,
19,
20]) and are based on examples of functions
g satisfying locally the assumptions of Theorem 1.
The first result is the following.
Theorem 2. Let and let be the unit ball in . Then, under assumptions , in and on μ, we getfor any functions . Proof. Reasoning as in the proof of Theorem 1, we set
,
. Then, the function
W in
is given by
To get the integrability required in
in
, it is sufficient that the weights
are such that
,
. More precisely, pointing out that
if
K is a compact set in
, we get
and, about the last term on the right-hand side in (
22),
Finally, since
attained for
, we get the result. □
In the case of a weight
,
, inequality (
21), for
and
, is the local version of (
20) with
.
Another example of weight is given by
,
and
. In the last case, the condition (
12) in
is satisfied for
and
.
For
, inequality (
21) turns out to be the improved Hardy inequality with a Lebesgue measure in [
17,
18,
20].
A further local inequality follows.
Theorem 3. Let and let be the unit ball in . Then, under assumptions , in and on μ, we getfor any functions and . Proof. It is enough to consider
,
, observing that
□
Finally, we remark that for
and
, we almost get the estimate in [
16,
19] in the sense that, in place of four in the left-hand side in (
23), the authors obtained
, where
is the first zero of the Bessel function
.
Moreover, in that case, the functions and more generally are good weights.
5. An Application to Evolution Problems
In the section, we give a motivation for our interest in Hardy inequalities with a weight. These estimates play a crucial role in achieving existence results for solutions to the problem
where
L is the Kolmogorov operator
defined on smooth functions, perturbed by a potential
, with
the sum of an inverse square potential and
V satisfying condition
.
We say that
u is a weak solution to (
P) if, for each
, we have
and
for all
having compact support with
, where
denotes the open ball of
of radius
R centered at 0. For any
,
is the parabolic Sobolev space of the functions
having weak space derivatives
for
and weak time derivative
equipped with the norm
An additional assumption on
allows us to get a semigroup generation on
(see [
23], Corollary 3.7).
, , , for some , and for any compact set
We remark that condition
implies
in
. Indeed, if
, then
and
. Moreover,
since
. Thus, we get
An example of a weight function satisfying is , .
In the applications to evolution problems with Kolmogorov operators, we need
-semigroup generation results, when reasoning as in [
9,
11,
13]. Operators of a more general type for which the generation of a semigroup was stated can be found, for example, in [
24], in the context of weighted spaces.
The bottom of the spectrum of
is defined as follows
The authors in [
11] stated the following result with a proof similar to the one given in [
21]. We include hypothesis
in
to get the density result.
Theorem 4. Assume that μ satisfies in and . Let . Then, if , there exists a positive weak solution of satisfying the estimatefor some constants and . The existence result below relies on Theorems 1 and 4.
Theorem 5. Assume hypotheses in and –. Then, there exists a positive weak solution of satisfyingfor some constants , . Proof. The weighted Hardy inequality (
14) implies that
. Then, the result is a consequence of Theorem 4. □
6. Conclusions
This paper fits into the context of weighted Hardy type inequalities in . These estimates apply to the study of Kolmogorov operators, with the weight function in the drift term, perturbed by singular potentials. The research project on this topic during the last years involved the case of inverse square potentials with a single pole and with n poles, with a Gaussian measure and with measures of a more general type. Later, the inequality was extended to the case of different potentials in the unipolar case.
In this paper, the potential was given by inverse square potentials perturbed by a nonnegative term
V. As a consequence, we improved previous results in [
12] concerning estimates in
. We were interested in a suitable class of weights which included Gaussian functions and weights involving a distance to the origin.
The method used to get the results was based on the introduction of a suitable vector-valued function and on a generalized vector field method. This technique enabled us to also get some local estimates with examples of functions V, weighted versions of well-known estimates stated in the case of a Lebesgue measure.
Future developments will consider the case of n poles in a different case from potentials with multiple inverse square singularities, with attention to general methods to get the estimates.