1. Introduction
Killing vector fields are infinitesimal generators of isometries on a Riemannian manifold
. They satisfy the condition
, i.e., the Lie derivative of the metric in their direction to vanish. A more general notion, namely, the 2-Killing vector field, has been introduced in [
1] as being a smooth vector field
such that
. Obviously, any Killing vector field is also 2-Killing, but in general, the converse is not true. Therefore, a first question which can arise is the following:
When does a 2-Killing vector field reduces to a Killing vector field? In his paper [
1], Oprea established some relations between them, and he gave a necessary and sufficient condition in terms of the Ricci curvature of the Levi-Civita connection of
g for a 2-Killing vector field to be parallel, hence, a Killing vector field.
On the other hand, solitary waves preserving their shape while propagating with a constant speed, which are known as solitons, are mathematically modeled as stationary solutions to a certain flow. They are described by a second-order nonlinear equation and have concrete applications in nonlinear dynamics. In Riemannian geometry, Ricci solitons correspond to the Ricci flow, which was first considered by Hamilton in [
2]. The Ricci soliton equation is
with
as a real constant, which reduces to the Einstein condition when
is a Killing vector field. Another type of recently considered soliton, namely, the hyperbolic Ricci soliton [
3], which is defined by
with
and
two real constants, also reduces to an Einstein manifold if
is a Killing vector field and to a Ricci soliton if
is a 2-Killing vector field.
Spacetimes, which are mathematically described as Lorentzian manifolds, model the physical world. Through the important particular spacetimes counts those that occur when the manifold is a warped product of a certain type: either a generalized Robertson–Walker spacetime
or a standard static spacetime
[
4]. It is worth mentioning that the manifolds of warped product type, introduced by Bishop and O’Neill [
5], are of special interest in physics. Doubly warped products are some of their generalizations [
6,
7].
It is known that the existence of distinguished vector fields on Riemannian manifolds dictates their geometry. Killing vector fields on doubly warped products have already been treated in [
6,
8]. In the present paper, which extends some of the above-mentioned results, we firstly provide a necessary and sufficient condition for a vector field, which satisfies the condition that the second Lie derivative of the metric in its direction is traceless (in particular, a 2-Killing vector field) to be a parallel vector field, hence a Killing vector field. We consider Killing and 2-Killing vector fields on doubly warped products, and we establish some consequences on the factor manifolds. In particular, we characterize the factor manifolds as being isometric to the Euclidean space when there exists a Killing vector field on the doubly warped product, and we provide the necessary and sufficient conditions for a doubly warped product to reduce to a direct product when there exists a 2-Killing vector field on the factor manifolds. We also show that, under a certain assumption, a factor manifold is a Ricci soliton having as a potential vector field the component of a Killing vector field on the doubly warped product manifold if and only if it is Einstein, and we show that an Einstein factor
,
of a doubly warped product endowed with a 2-Killing vector field
is a nontrivial hyperbolic Ricci soliton with the potential vector field
,
. As physical applications, we characterize Killing and 2-Killing vector fields on doubly warped spacetimes and, in particular, on the standard static spacetime and on the generalized Robertson–Walker spacetime. Our paper continues and completes with new properties that expand on the results obtained in [
8,
9], where the authors also provided some characterizations of the Killing and 2-Killing vector fields on the standard static spacetime and on the generalized Robertson–Walker spacetime.
2. On 2-Killing Vector Fields
A smooth vector field
on a pseudo-Riemannian manifold
is called Killing if
, and it is called 2-Killing [
1] if
where
stands for the Lie derivative of a symmetric
-tensor field
T in the direction of
, which is given by
for any smooth vector fields
on
M.
Any Killing vector field is 2-Killing too, but not conversely. Nontrivial cases when a 2-Killing vector field is also Killing were given in [
1,
10]. We shall extend here some of those results.
Lemma 1. Let be smooth vector fields on . Then,where , and ∇ stands for the Levi-Civita connection of g. In particular, for
, taking into account that the Riemannian curvature
R of ∇ satisfies
we obtain the conclusion.
Lemma 2 ([
1])
. Let be smooth vector fields on . Then, The result of Theorem 2.2 from [
1] can be extended as follows.
Proposition 1. Let ξ be a smooth vector field on a compact Riemannian manifold . If and , then ξ is a parallel vector field.
Proof. Let
be a local orthonormal frame field on
M, where
. Then, we have
from Lemma 2. By taking the sum in the previous relation, we obtain
By integrating the relation above with respect to the canonical measure, we find
and, hence,
. □
From the previous proposition, we can state the following theorem.
Theorem 1. If ξ is a smooth vector field on a compact Riemannian manifold such that , then ξ is a parallel vector field if and only if .
3. Describing 2-Killing Vector Fields on Doubly Warped Products
Let
and
be two pseudo-Riemannian manifolds, let
and
be the Levi-Civita connections of
and
, respectively, and let
and
be two positive smooth functions on
and
, respectively. We consider the
doubly warped product manifold , which is defined [
6,
7] as
and where
is the canonical projection,
. If only one of
and
is a constant, then
is a warped product manifold (see [
5]). Moreover, if both
and
are constants, then
is a direct product manifold (and we call it the trivial case).
For the rest of this paper, we shall use the same notation for a function on , and its pullback on , for a metric on , and its pullback on , and also for a vector field on , and its lift on . The set of smooth sections of a smooth manifold M will be denoted by .
We have the orthogonal decomposition
and for any
, we denote
where
,
.
The expressions of the first and the second Lie derivatives are given in the following proposition.
Proposition 2. Let . Then, for any , , we have: Proof. The expression of the first Lie derivative on a doubly warped product manifold has been previously given in [
8].
For
,
,
, we have
Then,
and the proof is complete. □
If one of the components of is Killing or 2-Killing, or if is a Killing or a 2-Killing vector field, then from the above proposition, we deduce the following proposition.
Proposition 3. - (i)
If is a Killing vector field on , then we have the following:
- (a)
its lift is a Killing vector field on if and only if ;
- (b)
its lift is a 2-Killing vector field on if and only if
- (ii)
If and are Killing vector fields on and , respectively, then we have the following:
- (a)
is a Killing vector field on if and only if and ;
- (b)
is a 2-Killing vector field on if and only if
- (iii)
If is a 2-Killing vector field on , then its lift is a 2-Killing vector field on if and only if - (iv)
If and are 2-Killing vector fields on and , respectively, then is a 2-Killing vector field on if and only if
As a consequence, we have the following corollary.
Corollary 1 ([
9])
. If is a warped product manifold, then we have the following:- (i)
is a Killing vector field on if and only if its lift is a Killing vector field on ;
- (ii)
is a 2-Killing vector field on if and only if its lift is a 2-Killing vector field on .
Proposition 4. - (i)
If is a Killing vector field on , then is a Killing vector field on if and only if .
- (ii)
If is a 2-Killing vector field on , then is a 2-Killing vector field on if and only if
As a consequence, we have the following corollary.
Corollary 2 - (i)
If is a Killing vector field on the warped product , then is a Killing vector field on .
- (ii)
If is a 2-Killing vector field on the warped product , then is a 2-Killing vector field on .
Example 1. We consider the Heisenberg group equipped with the Riemannian metric , where denote the standard coordinates in , and . Then, defines a Sasakian structure on M, whereand ξ is a Killing, hence, a 2-Killing vector field on M. Let be the doubly warped spacetime, where I is a connected open real interval equipped with the metric , and , , with .
Then, according to Proposition 3 (i)(b), the lift of ξ to is a 2-Killing vector field. On the other hand, if we take as a constant, then the lift of ξ to the standard static spacetime is a Killing, hence, a 2-Killing vector field.
We shall further characterize the factor manifolds of a doubly warped product as being Ricci-type solitons having as a potential vector field the component of a Killing or a 2-Killing vector field on the doubly warped product.
We recall that
is called a
Ricci soliton [
2] if the vector field
and the scalar
satisfy
where Ric is the Ricci curvature of
.
Theorem 2. Let be a Killing vector field on . Then, we have the following:
- (i)
is a Ricci soliton if and only if is an Einstein manifold; in this case, , where is the scalar curvature of and ;
- (ii)
if is a complete Riemannian manifold, for a smooth function on , and is a nonzero constant, then, is isometric to the Euclidean space.
Proof. If
is a Ricci soliton, then, for any
, we have
and, from Proposition 2, we obtain
which, by taking the trace, gives us
Conversely, if
, then
with
, and we obtain (i).
For (ii), we notice that
for any
, and we obtain the conclusion from Tashiro’s theorem [
11]. □
We recall that
is called a
hyperbolic Ricci soliton [
3] if the vector field
and the scalars
satisfy
where Ric is the Ricci curvature of
.
We remark that if is a Killing vector field, then the manifold is an Einstein manifold provided that , and if is a 2-Killing vector field, then the manifold is a Ricci soliton. If none of these particular cases occurs, we shall call the soliton nontrivial.
Theorem 3. Let be a 2-Killing vector field on . If is a nonzero constant and is an Einstein manifold, then is a nontrivial hyperbolic Ricci soliton; in this case, and , where is the scalar curvature of , and .
Proof. From Proposition 2, we obtain that
for any
. Since
and
, we obtain
for any
; hence, we have the conclusion. □
Also, we have the following corollary.
Corollary 3. If is a 2-Killing vector field on the warped product and is an Einstein manifold, then is a nontrivial hyperbolic Ricci soliton; in this case, , and , where is the scalar curvature of , and .
Now, we will provide necessary and sufficient conditions for a doubly warped product manifold to reduce to a direct product.
Theorem 4. Let be a smooth vector field on the connected Riemannian factor manifold , , of the doubly warped product , such that =0 for . Then, is a parallel vector field if and only if is a parallel vector field on and is a constant for , i.e., the manifold is a direct product manifold.
Proof. Let
and
be local orthonormal frame fields on
and
, respectively, where
for
. Then,
is a local orthonormal frame field on
. We have
For
, we have [
6]
where
denotes the gradient of a function
f on the doubly warped product manifold.
After a long computation, we obtain
Considering the hypotheses, we infer
and we obtain the conclusion. □
As a consequence, we have the following corollary.
Corollary 4. There do not exist nontrivial doubly warped products with connected Riemannian factor manifolds admitting a parallel vector field satisfying and = 0 for .
Now, using Proposition 1 and Theorem 4, we extend from warped products to doubly warped products (and use a weaker hypothesis) Shenawy and Ünal’s result from Theorem 3.2 of [
9].
Theorem 5. Let be a smooth vector field on the compact and connected Riemannian factor manifold , , of the doubly warped product such that = 0 for . If and for , then is a parallel vector field if and only if is a constant for , i.e., the manifold is a direct product manifold.
Proof. From Proposition 1, we deduce that
is a parallel vector field on
,
, and, considering the hypotheses, we infer
from Theorem 4; hence, we have the conclusion. □
Remark 1. Since the behavior with respect to the two factor manifolds of a doubly warped product is the same, all the results obtained in this section regarding one of the factors are also valid for the other one.
4. The Spacetime Case
Let be a doubly warped spacetime, where I is a connected open real interval equipped with the metric , and is a three-dimensional Riemannian manifold. If is a constant, then the manifold is the standard static spacetime, and if is a constant, then it is the generalized Robertson–Walker spacetime.
We will consider both the Killing and 2-Killing cases, wherein some properties for the Killing case being studied are also found in [
7,
8] and for the 2-Killing case are found in [
9].
Lemma 3. If , with u being a smooth function on I, then Proof. For any vector fields
and
, we have the following:
We can now conclude the following.
Proposition 5. If , with u being a smooth function on I, then, we have the following:
- (i)
ξ is a Killing vector field on if and only if u is a constant;
- (ii)
ξ is a 2-Killing vector field on if and only if
Proof. From Lemma 3, we deduce that is a Killing vector field on if and only if , and is a 2-Killing vector field on if and only if ; hence, we have the conclusion. □
Now, we will provide the necessary and sufficient condition for a vector field on a doubly warped spacetime to be Killing or 2-Killing.
Theorem 6. Let , with u being a smooth function on I and . Then, we have the following:
- (i)
ξ is a Killing vector field on the doubly warped spacetime if and only if - (ii)
ξ is a 2-Killing vector field on the doubly warped spacetime if and only if
Proof. Let
. By replacing the expressions of
and
from Lemma 3 into Proposition 2, we consequently have
If
is a Killing vector field, then
which is equivalent to
If
is a 2-Killing vector field, then
and we obtain the conclusion. □
Example 2. According to Theorem 6 (ii), the lift of any vector field to the doubly warped spacetime is a 2-Killing vector field.
In particular, we have the following results.
Corollary 5. Let , with being a smooth function on I. Then, we have the following:
- (i)
the lift of ξ is a Killing vector field on the doubly warped spacetime if and only if in this case, the manifold is a standard static spacetime;
- (ii)
the lift of ξ is a 2-Killing vector field on the doubly warped spacetime if and only if in this case, for some .
Proof. It follows from Theorem 6. □
Example 3. According to Corollary 5 (ii), the lift of the vector field on I, to the doubly warped spacetime is a 2-Killing vector field if and only if the warping function satisfies for some .
Corollary 6. Let , with u being a constant and . Then, we have the following:
- (i)
ξ is a Killing vector field on the doubly warped spacetime if and only if - (ii)
ξ is a 2-Killing vector field on the doubly warped spacetime if and only if
Proof. It follows from Theorem 6. □
Corollary 7. Let , with being a constant. Then, we have the following:
- (i)
the lift of ξ is a Killing vector field on the doubly warped spacetime if and only if that is, the manifold is a standard static spacetime;
- (ii)
the lift of ξ is a 2-Killing vector field on the doubly warped spacetime if and only if
Proof. It follows from Corollary 5. □
Proposition 6. Let , with being a constant and ζ being a Killing vector field on . Then, we have the following:
- (i)
ξ is a Killing vector field on the doubly warped spacetime if and only if that is, is constant on the integral curves of ζ, and the manifold is a standard static spacetime;
- (ii)
ξ is a 2-Killing vector field on the doubly warped spacetime if and only if
Proof. It follows from Theorem 6. □
For the standard static spacetime, we deduce the following proposition.
Proposition 7. If , with and u being a smooth function on I, then we have the following:
- (i)
ξ is a Killing vector field on the standard static spacetime if and only if - (ii)
ξ is a 2-Killing vector field on the standard static spacetime if and only if
Moreover, if u is a constant, then we have the following:
- (i’)
ξ is a Killing vector field on the standard static spacetime if and only if - (ii’)
ξ is a 2-Killing vector field on the standard static spacetime if and only if
Proof. It follows from Theorem 6. □
Remark 2. Let , with and u being a smooth function on I. If ξ is a Killing vector field on , then ζ is a Killing vector field on , and if ξ is 2-Killing on , then ζ is also 2-Killing on .
Corollary 8. If , with u being a smooth function on I, then we have the following:
- (i)
the lift of ξ is a Killing vector field on the standard static spacetime if and only if u is a constant;
- (ii)
the lift of ξ is a 2-Killing vector field on the standard static spacetime if and only if
Moreover, if u is a constant, then the lift of ξ is a Killing, hence, a 2-Killing vector field on the standard static spacetime.
Proof. It follows from Proposition 7. □
For the generalized Robertson–Walker spacetime, we deduce the following proposition.
Proposition 8. If , with u being a smooth function on I and , then we have the following:
- (i)
ξ is a Killing vector field on the generalized Robertson–Walker spacetime if and only if - (ii)
ξ is a 2-Killing vector field on the generalized Robertson–Walker spacetime if and only if
Proof. It follows from Theorem 6. □
Corollary 9. If , with being a smooth function on I, then we have the following:
- (i)
the lift of ξ is a Killing vector field on the generalized Robertson–Walker spacetime if and only if that is, the manifold is a direct product;
- (ii)
the lift of ξ is a 2-Killing vector field on the generalized Robertson–Walker spacetime if and only if
Moreover, if u is a constant, then the lift of ξ is a Killing or a 2-Killing vector field on the generalized Robertson–Walker spacetime if and only ifthat is, the manifold is a direct product. Proof. It follows from Proposition 8. □
Example 4. We consider the generalized Robertson–Walker spacetime , with and . Then, according to Corollary 9 (ii), the lift of the vector field on I, where , to is a 2-Killing vector field.