1. Introduction
The concept of Riemann flow was introduced by C. Udrişte in [
1,
2]. It refers to the flow associated with the evolution equation
where
R is the Riemann curvature tensor of type
corresponding to the metric
g at time
t and
stands for the Kulkarni–Nomizu product of two symmetric tensors of type
; e.g., this product has the following form for order-2 covariant tensors
g and
h:
Here and further x, y, z, and w stand for arbitrary vector fields on a smooth manifold M.
Riemann solitons were introduced by I. E. Hirică and C. Udrişte in [
3]. They are critical metrics for Riemann flow as they are self-similar solutions of its evolution equation, i.e., it evolves over time from a given Riemannian metric on
M by means of diffeomorphisms and dilatations.
A Riemannian metric
g on a smooth manifold
M is said to be a
Riemann soliton if there exists a differentiable vector field
and a real constant
such that [
3]
where
is the Lie derivative along
. Such a vector field
is known as the
potential of the soliton. In the case in which
is a differentiable function on
M, then
g is called an
almost-Riemann soliton. If
is Killing, i.e.,
, then
M is a manifold of constant sectional curvature. In this sense, the Riemann soliton is a generalization of a space of constant curvature.
In early studies [
3], the notion of the Riemann soliton was studied in the context of Sasakian geometry and it was known as the Sasaki–Riemann soliton.
In recent years, some interesting results have been obtained for Riemann solitons and almost-Riemann solitons on almost-contact metric manifolds. In [
4,
5], Venkatesha, Devaraja and Kumara studied the cases of almost-Kenmotsu manifolds and K-contact manifolds. Biswas, Chen and U. C. De characterized almost-co-Kähler manifolds whose metrics are Riemann solitons in [
6]. K. De and U. C. De proved in [
7] some geometric properties of almost-Riemann solitons on non-cosymplectic normal almost-contact metric manifolds and in particular on quasi-Sasakian 3-dimensional manifolds. In [
8], Chidananda and Venkatesha studied Riemann solitons on non-Sasakian
-contact manifolds in relation with the
-Einstein property, where the potential is an infinitesimal contact transformation or collinear to the Reeb vector field.
A.-M. Blaga contributed to the study of Riemann and almost-Riemann solitons in [
9] for Riemannian manifolds, together with Laţcu, and in [
10] for
-contact metric manifolds. In the latter case, compact Riemann solitons with constant-length potential were shown to be trivial. This result was extended by Tokura, Barboza, Batista, and Menezes in [
11] without additional conditions on the potential.
-homothetic deformations were introduced by S. Tanno [
12] in almost-contact metric geometry, where
denotes the contact distribution. These transformations preserve the K-contact or Sasakian properties of a structure. In [
13], Blaga studied almost-Riemann solitons on a
-homothetically deformed Kenmotsu manifold with different conditions on the potential and explicitly obtain Ricci and scalar curvatures for some cases.
An
almost-contact complex Riemannian (or accR for short) manifold is an odd-dimensional pseudo-Riemannian manifold
M equipped with a B-metric
g and an almost-contact structure
and therefore
M has a codimension-one distribution
equipped with a complex Riemannian structure. These manifolds are also known as
almost-contact B-metric manifolds [
14].
What mainly distinguishes an accR structure from the better-known almost-contact metric structure is the presence of another metric of the same type associated with the given metric. Both B-metrics have a neutral signature on
and the restriction of
on
(actually, an almost-complex structure) acts as an anti-isometry on the metric. Manifolds of this type have been studied and investigated, for example, in [
14,
15,
16,
17,
18,
19,
20,
21,
22,
23,
24,
25,
26,
27].
The aim of this paper was to investigate the interaction between almost-Riemann solitons and the accR structure. One way to realize this goal is to use conformal transformations of the accR structure. Contact conformal transformations of B-metric were introduced and initially studied in [
23,
24] by K. Gribachev and the author. The metric deformation depends on both the two B-metrics and their restriction on the vertical distribution determined by
. A generalization of these transformations and the
-homothetic deformations of the accR structure (introduced in [
28]) that use a triplet of functions on the manifold are the following transformations. Contact conformal transformations of a general type that transform not only the B-metrics but also
and
were studied in [
18]. According to this work, the class of accR manifolds, which is closed under the action of these transformations, is the direct sum of the four main classes among the eleven basic classes of these manifolds, known from the classification of Ganchev–Mihova–Gribachev presented in [
14]. The main classes are designated as those for which the manifolds are characterized by the fact that the covariant derivative of the structure tensors with respect to the Levi–Civita connection of any of the B-metrics is expressed only by a pair of B-metrics and the corresponding traces.
The present paper is organized as follows.
Section 2 recalls the basic concepts of accR manifolds and contact conformal transformations of the structure tensors on them.
Section 3 introduces the notion of an almost-Riemann soliton with vertical potential on a transformed accR manifold and demonstrates the conditions that imply the flatness of the manifold.
Section 4 presents the curvature properties of contact conformal accR manifolds that are transformed from such manifolds of cosymplectic type and admit the studied soliton.
Section 5 is devoted to the particular case of the situation discussed in the previous section when the transformed manifold is also of cosymplectic type. The last two sections provide explicit examples for the studied manifolds in relation with the obtained results.
2. Almost-Contact Complex Riemannian Manifolds and Their Contact Conformal Transformations
Here we study
almost-contact complex Riemannian manifolds or
accR manifolds for short, also known as
almost-contact B-metric manifolds. Such a manifold, denoted by
, is a
-dimensional differentiable manifold, which is equipped with an almost-contact structure
and the B-metric
g. This means that
is an endomorphism of the tangent bundle
,
is a Reeb vector field, and
is its dual contact 1-form. Moreover,
g is a pseudo-Riemannian metric of signature
satisfying the following algebraic relations: [
14]
where
is the identity transformation on the set
of vector fields on
M.
As consequences of (
2), the following equations are known:
where ∇ is the Levi-Civita connection of
g.
The investigated manifold
has another B-metric in addition to
g. This is the associated metric
of
g on
M, defined by
Obviously,
as well as
g satisfies the last condition in (
2) as well and has the same signature.
A classification of accR manifolds containing eleven basic classes
,
, ⋯,
is given in [
14]. This classification is made with respect to the tensor
F of type
defined by
The following identities are valid:
The special class , determined by the condition , is the intersection of the basic classes and it is known as the class of the cosymplectic accR manifolds. Sometimes, in the context of classification and for brevity, these manifolds are called -manifolds.
Let
be a basis of
and let
be the inverse matrix of the matrix
of
g. Then the following 1-forms are associated with
F:
These 1-forms are known also as the Lee forms of the considered manifold. Obviously, the identities and are always valid.
In [
23], the so-called contact conformal transformation of the B-metric
g is introduced. It maps
g into a new B-metric
using both the B-metrics. Later, in [
18], this transformation is generalized as a contact conformal transformation that gives an accR structure
as follows:
where
are differentiable functions on
M. The group of these transformations is denoted by
G and for brevity we call each of the elements of
G a
G-transformation.
Note that the
G-transformations of
are a generalization of the
-homothetic deformations, where
denotes the contact distribution
. Namely, for a positive constant
, a
-homothetic deformation is defined by [
28] (see also [
29] (p. 125) for the metric case)
It is clear that
-homothetic deformation is a
G-transformation of the accR structure
for constants
,
, and
.
The structure
determines two mutually orthogonal distributions with respect to
g. They are the horizontal (contact) distribution
and the vertical distribution
. They coincide with the respective distributions for the structure
, i.e.,
and
, due to the equalities in the first line of (
3).
The corresponding tensors
F and
for the accR structures
and
are related by means of a
G-transformation (
3) as follows (e.g., [
18]; see also [
25])
where for brevity we use the following notation:
In the general case, the relations between the Lee forms of the corresponding manifolds
and
are as follows (see [
18]):
As proven in [
20] (Theorem 4.2, p. 62), the class of accR manifolds that is preserved by
G-transformations is the direct sum of all main classes
, denoted here for brevity as
. The main classes are the only classes of accR manifolds in the Ganchev–Mihova–Gribachev classification, where
F is expressed only by the metric
-tensors
g,
,
, and the Lee forms. The class
obviously contains
.
3. Almost Riemann Solitons with Vertical Potential on Contact Conformal accR Manifolds
Definition 1. It can be said that the B-metric generates a Riemann soliton
with potential and constant , denoted , on an accR manifold , if the following condition is satisfied:where is the Riemannian curvature tensor of for . If is a differentiable function on M, then the generated soliton is called an almost-Riemann soliton
on . In this work, we consider the case in which the potential is a vertical vector field, i.e., is collinear to . Then we have the expression for a differentiable function on the manifold. Obviously, the equality holds. We require that the potential does not degenerate at any point on the manifold . This means that does not vanish anywhere, i.e., .
The following expression of the Lie derivative in terms of the covariant derivative with respect to the Levi-Civita connection
of
is well-known:
Similarly, the following formula can be obtained:
For a vertical potential we have
Then, the latter two equalities imply the formula
where we use the following notation
Obviously, the
-tensor
is symmetric and has the properties
Therefore, it vanishes on . Furthermore, vanishes if and only if is a constant.
The following theorem holds for an arbitrary -manifold M. It is not necessary to assume that the structure of M is obtained by means of some G-transformation.
Theorem 1. Every -manifold admitting an almost-Riemann soliton with vertical potential is flat.
Proof. Let us consider an
-manifold
admitting an almost-Riemann soliton
with vertical potential
. Then its curvature tensor for
g has the following form, similar to (
7):
Since
vanishes on an
-manifold, then we have
. Due to the equality
, which is the analogue of (
8) on
, we can observe in this case that
where we use the following notation, similarly to (
10):
Thus, the curvature tensor of such a manifold
takes the form
Using (
11) and (
12), we obtain the Ricci tensor and scalar curvatures for
g and
, respectively, given in the following expressions:
The Riemannian curvature tensor
R of an
-manifold has the Kähler property
since
,
, and
are covariant constant on
M with respect to ∇ [
24]. As consequences of (
15) and (
11) we have
and
, respectively, which, together with (
13), imply that
On the other hand, by virtue of (
12) and (
1), we obtain
where we use the notations
,
. Then, taking into account the fact that
and
are traceless due to the properties of
, the equalities (
15) and (
17) consequently yield
Comparing the values of
in (
18) and (
14), we obtain
, which due to (
16) gives
. Therefore, from (
18) it follows that
, which, together with (
13), implies that
and then
, bearing in mind (
12). □
4. -Manifolds Admitting the Studied Solitons
In this section, we consider
as an
-manifold, i.e.,
. Let the resulting accR manifold
via a
G-transformation be called a
-manifold. Then, the following expression follows from (
4) and gives the form of the fundamental tensor of
:
Then, using (
5) and (
6), the corresponding Lee forms are specialized as follows:
Theorem 2. A -manifold admitting an almost-Riemann soliton with vertical potential has a curvature tensor of the following form:where Proof. Bearing in mind (
7), we have to determine
. The expression of the Lie derivative of
along
for a
-manifold is given in [
22] in the form:
Using the second line in (
3), we derive the following formulas:
which we apply in (
21), together with the first line in (
3). In this way, we obtian
where we introduce the notation (
20). Obviously,
is a symmetric
-tensor having the following properties:
Moreover, the formula is valid. It is easy to conclude that vanishes if and only if the function w is constant on , i.e., .
The formula in (
22) can be rewritten in the following form:
Then we substitute the last equality in (
9) and get the following
Using the Kulkarni–Nomizu product for
and the last obtained Lie derivative, we obtain
Then, according to (
7) and (
23), we can establish the truthfulness of the statement. □
Taking the trace of (
19), we obtain the expression of the Ricci tensor of the almost-Riemann soliton satisfying the conditions of Theorem 2 as follows:
Now, we take the trace of the Ricci tensor in (
24) to obtain the scalar curvature of
as follows
Then, we compute the associated quantity
of
defined by
and using (
24), we obtain
For every
-manifold, the relation
is known from [
17], where
is the scalar curvature for
. However, for
-manifolds, which are outside of
, this is not true, so there we use the so-called
*-scalar curvature.
Corollary 1. A -manifold with an almost-Riemann soliton and a vertical potential has vanishing *-scalar curvature if and only if the function v is a vertical constant, i.e., .
Proof. This statement follows from (
26) and the condition that
is not identically zero; otherwise, it would lead to a degeneration of the potential
. □
In [
21], the notion of an
Einstein-like accR manifold
was introduced by means of the following condition for its Ricci tensor:
where
is some triplet of constants. In particular, when
and
, the manifold is called an
η-Einstein manifold and an
Einstein manifold, respectively. If
a,
b,
c are functions on
M, then the manifold satisfying condition (
27) is called
almost-Einstein-like, and in particular for
and
it is called an
almost-η-Einstein and
almost-Einstein manifold, respectively.
Theorem 3. A -manifold with an almost Riemann soliton and a vertical potential is an almost Einstein-like manifold if and only if the condition () is satisfied on .
The almost-Einstein-like manifold has the following Ricci tensor:and the expressions of the scalar curvatures are the same as those in (25) and (26). Proof. Bearing in mind (
24) and the definition of an almost-Einstein-like accR manifold, we can conclude that the considered manifold is almost Einstein-like if and only if
is a function multiple of
. Therefore, we have the following condition due to (
10) and (
20)
where
f is an arbitrary function on the manifold. An immediate consequence of (
29) for
is
. Then, we obtain
and in particular for
the function
is a vertical constant.
Applying
to the argument of (
29), we can observe the following consequence:
Since
is not zero, the last equation has the following solution:
restricted on
, where
is an arbitrary constant.
The formula in (
28) follows from (
24) and (
30). It implies the same expressions of
and
as in (
25) and (
26). □
Theorem 4. Let be a -manifold with an almost-Riemann soliton and a vertical potential. Then is:
- (i)
an almost-η-Einstein manifold if and only if v is a vertical constant, i.e., ;
- (ii)
an almost-Einstein manifold if and only if v is a vertical constant and the condition () is satisfied on .
Proof. The statements in (i) and (ii) are easily derived by considering the particular cases of (
27) that are reflected in (
28). The equality in (ii) is a solution of
. □
Corollary 2. Let be a -manifold with an almost-Riemann soliton and a vertical potential. Then the Ricci tensor and the scalar curvatures are the following when is:
- (i)
an almost-η-Einstein manifold: as in (25) and . - (ii)
an almost-Einstein manifold:
Corollary 3. A -manifold with an almost-Riemann soliton and a vertical potential is an Einstein-like manifold if and only if the functions , , u and v satisfy the following conditions:Moreover, is a Riemann soliton with a vertical potential on the Einstein-like manifold if and only if , , and are constants. Proof. The considered manifold is Einstein-like if and only if the three coefficients of
-tensors in (
28) are constants. This system of equations is equivalent to the equations in (
31). The case for the Riemann soliton follows from
and (
31). □
4.1. Example of an -Manifold of Dimension 5
A trivial example of an
-manifold
of an arbitrary dimension is given in [
14]. An accR structure is defined in the space
in the following way:
where
and
is the Kronecker delta.
In [
19] (see also [
20] (Example 5, p. 105)), we give an example of a pair of functions
on
for dimension 5, i.e.,
; it can be written as follows
where
,
and
.
It is shown that
satisfy the condition
; therefore, the
G-transformation determined by
deforms the given
-manifold into an
-manifold
defined by
where
. Its curvature tensor, the scalar curvature, and the ∗-scalar curvature are given in the form
Now, let us introduce an almost-Riemann soliton
with vertical potential
on
, assuming that we have the following functions:
which determine the soliton.
Bearing in mind Theorem 2, we can check the expression of
in (
19). Using (
32) and (
34), we compute successively
due to
,
,
,
, and obtain for the coefficients in (
19) the following:
Then (
19) takes the form
which is in agreement with (
33). Thus, we verify Theorem 2 and Corollary 1.
Using (
35), we can observe the following consequences:
We can thus conclude that the constructed manifold has negative scalar curvature and zero ∗-scalar curvature, and that it is almost -Einstein-like (a particular case of almost Einstein-like manifolds), which is not almost Einstein. These results support Corollary 1, Theorem 3, Theorem 4(i), and Corollary 2(i).
In addition, we can calculate the scalar curvature
with respect to
. In [
17] (see also [
20] (Corollary 2.4, p. 38)), the relation of this quantity to the ∗-scalar curvature is expressed. For the case under consideration, the given formula can be read in the following way:
Using the fact that
in the present example, we get
, i.e., it is also negative as
.
5. -Manifolds That Are -Manifolds and Admit the Studied Solitons
In this section, we consider an -manifold , i.e., . Moreover, the resulting manifold , via a G-transformation, is again in , i.e., .
To ensure that both considered manifolds are in
, the transformation between them must be of a subgroup
of the group
G and defined by the following conditions [
18]:
In this case, the relationship between the curvature tensors
R and
for
g and
, respectively, is known from [
20] (p. 83) (see also [
18,
24]) and can be written as follows:
where
and
Theorem 5. Let and its image via a -transformation be -manifolds. Then the corresponding scalar curvatures for the pair of B-metrics satisfy the relationswherefor and . Proof. Using (
37) with (
38) for the corresponding curvature tensors
R and
, through lengthy but standard calculations, we obtain expressions for the corresponding scalar curvatures given in (
39). □
Obviously, the trace
involved in (
40) is actually the Laplacian of
u for
g, usually denoted by
or
, whereas
is some kind of associated quantity of
using
.
Corollary 4. Let be an almost-Riemann soliton with vertical potential on and let the requirements of Theorem 5 be fulfilled. Then has constant scalar curvatures for both B-metrics g and .
Proof. According to Theorem 1,
is flat, i.e.,
and therefore we have
. Substituting the last equalities into (
39) and considering (
40), we get
In this way, we can obtain the conditions that the scalar curvatures of an -manifold must satisfy in order to be mapped by a -transformation to an -manifold, admitting an almost-Riemann soliton under study.
As a consequence of Theorem 5.2 in [
20] (p. 81), we can deduce for an
-manifold that the functions
and
are constants, which implies that
and
are constants. □
As is well known, the Bochner curvature tensor B on a Kähler manifold can be considered in some sense as an analogue of the Weyl curvature tensor, and the vanishing of B has remarkable geometric interpretations.
In [
24], the
Bochner curvature tensor of φ-holomorphic type for a curvature tensor with the Kähler property is introduced on an arbitrary accR manifold of dimension at least 7, i.e.,
. The Riemannian curvature tensor
R of an
-manifold has the Kähler property (
15) and the definition of the Bochner curvature tensor
as a tensor of type
corresponding to
R can be written in the following form:
where
.
Corollary 5. Let be an almost-Riemann soliton with vertical potential on of dimension at least 7 and let the requirements of Theorem 5 be fulfilled. Then the Ricci tensor of has the following form:where S is determined by (38). Moreover, , , τ and are constants. Proof. It is known from [
18] that
on an
-manifold is a contact conformal invariant of the group
, i.e.,
.
For the considered manifold
we obtained
. Hence,
also vanishes and this means
for
. Then, due to (
42), we can obtain an expression of
R as follows:
where
and
are constants, according to Corollary 4 and have values given in (
41).
Using the fact that the Ricci tensor is hybrid with respect to
, i.e.,
, on an
-manifold, we can rewrite (
44) in the following more compact form:
where
L is defined by
The vanishing of
and (
37) imply the following
Comparing (
47) with (
45), we deduce that
and consequently (
43) holds. Equalities (
40) and (
41) imply that
and
are also constants like
and
. □
Example of an -Manifold of Arbitrary Dimension
Let us consider again the
-manifold
that was described at the beginning of
Section 4.1.
In [
23], the following example of a pair of functions
on an accR manifold is given as follows:
It is shown that
is a
-holomorphic pair of functions, i.e., the conditions for them in (
36) are satisfied.
Let
w be the function
. Then, we have
, which implies
. As a result, (
36) holds and
determine a contact conformal transformation from
. This transformation deforms
into
, which is again an
-manifold.
Bearing in mind (
37) and the fact that
is flat, we obtain the curvature tensor of the resulting manifold in the form
where
S is denoted in (
38) and here
u is given in (
48). Then, we compute the scalar curvatures and they have the following values:
where
u and
v are given in (
48), and
This result supports Theorem 5.
Bearing in mind (
49), we obtain vanishing scalar curvatures
and
for
, i.e.,
is scalar-flat.
Since the two considered -manifolds are related by a transformation from , is flat and the Bochner curvature tensor is an invariant of for dimension at least 7, we deduce that .
Then, bearing in mind (
42), the curvature tensor
has an expression corresponding to (
45) with (
46), namely,
Let us recall from [
18] that if
ℓ is a
G-transformation determined by (
3) for functions
, then its inverse transformation
is the
G-transformation determined for the functions
. Then, the present example is in unison with Corollary 4 and Corollary 5.