The following group plays an essential role in the proof of our main results, Theorems 1 and 2. Set
and denote by
the group
endowed with the metric
. Then
is a Polish group, and the sets of the form
, where
V is a neighborhood at the unit
, form a base at the identity
. In [
5] (Theorem 1), we proved that the group
is reflexive and hence locally quasi-convex.
We use the next standard notations. Let
be the standard basis of the Banach space
, and let
be the canonical basis in the dual Banach space
, i.e.,
where 1 is placed in position
n. Then
is a dense subspace of
consisting of all vectors with finite support.
Proof. For simplicity and clearness of notations we set
and
. For every
, set
. It is clear that
in the weak
topology on
and hence in
. Therefore we can define the linear injective operator
and the monomorphism
setting (for all
)
Denote with
and
the topologies on
E induced from
and
, respectively. So
is a locally convex vector topology on
E and
is a locally quasi-convex group topology on
E. By construction,
, so taking into account Fact 1 and the Hahn–Banach extension theorem, we obtain
Step 1: The topologies τ and are compatible. By (
1), it is sufficient to show that each continuous character of
belongs to
. Fix
. Then (
1) implies that
for some
and
To prove that it is sufficient (and also necessary) to show that . Replacing, if needed, by , we assume that .
Suppose for a contradiction that
. Since
is continuous, Fact 1 shows that, for every
, there is a
such that
where
is a canonical
-neighborhood of zero
In what follows and are fixed as above. We distinguish between three cases.
Case 1: There is a subsequence such that as . As
and
, there is
such that
The first inequality in (
4) implies that there is
Set
, where the nonzero element is placed in position
. Then
for every
, and the second inequality of (
4) and (
5) imply
Therefore
. On the other hand, (
5) implies
Hence since . However, this contradicts (2).
Case 2: There is a subsequence and a number such that as . Choose
such that
Choose a finite subset
F of
and, for every
, a natural number
such that the following two conditions are satisfied:
and
(this is possible because
and
: so, if
the set
F can be chosen to have only one element, and if
, the set
F also can be easily chosen to be finite). Now we define
by
Then
for every
, and, by (7),
. Therefore
. On the other hand, (
6) and (
8) imply
Hence
which contradicts (
2).
Case 3: . Choose
such that (recall that
)
Since
, choose a finite subset
such that
Define
by
where
will be chosen afterwards. Then, for all
and arbitrary
s, we have
and
. Therefore
. On the other hand, we have
(to obtain the last inequality we put
for all
) and (
9) and (
10) imply
From the second inequality in (
9), we have
Using this inequality and (
11) and (
12), one can easily find a family
such that
and hence
which contradicts (
2).
Cases 1–3 show that the assumption is wrong. Thus the topologies and are compatible.
Step 2. The topology is strictly finer than the original topology τ. Thus, E is not a Mackey group. Indeed, it is clear that
in the norm topology
on
E. On the other hand, since
where
is placed in position
k, we obtain that
in the topology
. Since, by construction,
we obtain
as desired. □
Analogously we prove that the normed space
is not a Mackey group. To this end, let
be the standard basis of the Banach space
, and let
be the canonical dual sequence in the dual Banach space
, i.e.,
where 1 is placed in position
n. Then
is a dense subspace of
consisting of all vectors with finite support.
Proof. For simplicity and clearness of notations we set
and
. For every
, set
. It is clear that
in the weak
topology on
and hence in
. Therefore we can define the linear injective operator
and the monomorphism
setting (for all
)
Denote with
and
the topologies on
E induced from
and
, respectively. So
is a locally convex vector topology on
E and
is a locally quasi-convex group topology on
E. By construction,
, so taking into account Fact 1 and the Hahn–Banach extension theorem we obtain
Step 1: The topologies τ and are compatible. By (
13), it is sufficient to show that each continuous character of
belongs to
. Fix
. Then (
1) implies that
for some
and
To prove that it is sufficient (and also necessary) to show that . Replacing if needed by , we assume that .
Suppose for a contradiction that
is unbounded. Then there is a subsequence
such that
as
. Since
is continuous, Fact 1 shows that, for every
, there is a
such that
where
is a canonical
-neighborhood of zero
As
and
, there is
such that
The first inequality in (
16) implies that there is
Set
, where the nonzero element is placed in position
. Then
for every
, and the second inequality of (
16) and (
17) imply
Therefore
. On the other hand, (
17) implies
Hence
since
. However, this contradicts (
14).
Step 2. The topology is strictly finer than the original topology τ. Thus E is not a Mackey group. Indeed, it is clear that
in the norm topology
on
E. On the other hand, since
where
is placed in position
k, we obtain that
in the topology
. Since, by construction,
we obtain
as desired. □
We finish this note with the following problem.