Abstract
It is known that the difference tensor \(R \cdot C - C \cdot R\) and the Tachibana tensor \(Q(S,C)\) of any semi-Riemannian Einstein manifold \((M,g)\) of dimension \(n \ge 4\) are linearly dependent at every point of \(M\). More precisely \(R \cdot C - C \cdot R = (1/(n-1))\, Q(S,C)\) holds on \(M\). In the paper we show that there are quasi-Einstein, as well as non-quasi-Einstein semi-Riemannian manifolds for which the above mentioned tensors are linearly dependent. For instance, we prove that every non-locally symmetric and non-conformally flat manifold with parallel Weyl tensor (essentially conformally symmetric manifold) satisfies \(R \cdot C = C \cdot R = Q(S,C) = 0\). Manifolds with parallel Weyl tensor having Ricci tensor of rank two form a subclass of the class of Roter type manifolds. Therefore we also investigate Roter type manifolds for which the tensors \(R \cdot C - C \cdot R\) and \(Q(S,C)\) are linearly dependent. We determine necessary and sufficient conditions for a Roter type manifold to be a manifold having that property.
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1 Introduction
Let \(\nabla \), \(R\), \(S\), \(\kappa \) and \(C\) be the Levi-Civita connection, the Riemann–Christoffel curvature tensor, the Ricci tensor, the scalar curvature tensor and the Weyl conformal curvature tensor of a semi-Riemannian manifold \((M,g)\), \(n = \dim M \ge 2\), respectively.
It is well-known that the manifold \((M,g)\), \(n \ge 3\), is said to be an Einstein manifold ([1]) if at every point of \(M\) its Ricci tensor \(S\) is proportional to the metric tensor \(g\), i.e., \(S = \frac{\kappa }{n}\, g\) on \(M\). In particular, if \(S\) vanishes on \(M\) then it is called Ricci flat. We denote by \({\mathcal U}_{S}\) the set of all points of \((M,g)\) at which \(S\) is not proportional to \(g\), i.e., \({\mathcal U}_{S} \,:= \, \{x \in M\, | \, S - \frac{\kappa }{n}\, g \ne 0\ \text{ at }\ x \}\). The manifold \((M,g)\), \(n \ge 3\), is said to be a quasi-Einstein manifold if at every point \(x \in {\mathcal U}_{S}\) we have \(\text{ rank }\, (S - \alpha \, g) = 1\), for some \(\alpha \in \mathbb {R}\), i.e., \(S = \alpha \, g + \varepsilon \, w \otimes w\), for some \(\alpha \in \mathbb {R}\), where \(w\) is a non-zero covector at \(x\) and \(\varepsilon = \pm 1\). We mention that quasi-Einstein manifolds arose during the study of exact solutions of the Einstein field equations and investigation on quasi-umbilical hypersurfaces of conformally flat spaces, see, e.g., [2] and references therein.
An extension of the class of semi-Riemannian Einstein manifolds is formed by the manifolds for which we have \(\nabla S = 0\). Manifolds satisfying the last condition are called Ricci-symmetric. Locally symmetric manifolds, for which we have \(\nabla R = 0\), constitute an important subclass of the class of Ricci-symmetric manifolds. The last relation implies the integrability condition
where \({\mathcal {R}}(X,Y ) \cdot \) denotes the derivation obtained from the curvature endomorphism \({\mathcal {R}}(X,Y )\) and \(X, Y\) are vector fields on \(M\). We refer to Sect. 2 for the precise definitions of the symbols used here. Manifolds satisfying (1.1) are called semisymmetric manifolds ([3]). Semisymmetric manifolds form a subclass of the class of pseudosymmetric manifolds. A semi-Riemannian manifold \((M,g)\), \(n \ge 3\), is said to be pseudosymmetric ([2, 4, 5]) if the tensors \({\mathcal {R}}(X,Y ) \cdot R\) and \((X \wedge _{g} Y ) \cdot R\) are linearly dependent at every point of \(M\). This is equivalent to
on \({\mathcal U}_{R} := \{x \in M\, | \, R - \frac{\kappa }{(n-1)n}\, G \ne 0\ \text{ at }\ x \}\), where \(L_{R}\) is some function on this set and the tensor \(G\) is defined by \(G(X,Y,W,Z) = g( X \wedge _{g} Y (Z), W)\). A geometric interpretation of the notion of pseudosymmetry is given in [6]. Further, a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), is said to be a manifold with pseudosymmetric Weyl tensor ([2, 4, 7]) if the tensors \({\mathcal {C}}(X,Y) \cdot C\) and \((X \wedge _{g} Y ) \cdot C\) are linearly dependent at every point of \(M\). This is equivalent to
on \({\mathcal U}_{C} := \{x \in M\, | \, C \ne 0\ \text{ at }\ x \}\), where \(L_{C}\) is some function on this set, \({\mathcal {C}}(X,Y ) \cdot \) denotes the derivation obtained from the Weyl conformal curvature endomorphism \({\mathcal {C}}(X,Y )\), and the Weyl conformal curvature tensor \(C\) is defined by \(C(X,Y,W,Z) = g( \mathcal {C}(X,Y) (Z), W)\). It is known that (1.3) is invariant under the conformal deformations of the metric tensor \(g\). We also note that \({\mathcal U}_{S} \cup {\mathcal U}_{C} = {\mathcal U}_{R}\).
In what follows, for a \((0,k)\)-tensor \(T\) and a symmetric \((0,2)\)-tensor \(A\) on a manifold \((M,g)\) we will denote the tensors \({\mathcal {R}}(X,Y) \cdot T\), \({\mathcal {C}}(X,Y) \cdot T\) and \((X \wedge _{A} Y) \cdot T\) by \(R \cdot T\), \(C \cdot T\) and \(Q(A,T)\), respectively. The tensor \(Q(A,T)\) is called the Tachibana tensor (see, e.g., [8]). In particular, we have the following \((0,6)\)-tensors: \(R\cdot R\), \(R\cdot C\), \(C \cdot R\), \(C \cdot C\) and the Tachibana tensors: \(Q(g,R)\), \(Q(S,R)\), \(Q(g,C)\), \(Q(S,C)\). Then we can write (1.2) and (1.3) in the form
and
respectively. We note that if (1.4) and (1.5) hold on the subset \({\mathcal U} = {\mathcal U}_{S} \cap {\mathcal U}_{C}\) of a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), then
on this set, where \(\lambda \) is some function ([7] Theorem 3.1). In addition, if \((M,g)\) is a non-quasi-Einstein manifold then from (1.6) it follows that on some open subset \({\mathcal U}_{1} \subset {\mathcal U}\) its curvature tensor \(R\) is a linear combination of the Kulkarni–Nomizu products \(S \wedge S\), \(g \wedge S\) and \(G = \frac{1}{2}\, g \wedge g\), i.e.,
on \({\mathcal U}_{1}\), where \(\phi \), \(\mu \) and \(\eta \) are some functions on this set ([7] Theorem 3.2 (ii)). A semi-Riemannian manifold \((M,g)\), \(n \ge 4\), satisfying (1.7) on \({\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\) is called a Roter type manifold ([9]). We refer to [10] for a survey on that class of manifolds.
We can check that on any Einstein manifold \((M,g)\), \(n \ge 4\), the tensors \(Q(g,R)\), \(Q(S,R)\), \(Q(g,C)\) and \(Q(S,C)\) satisfy
Further, in [11](Theorem 3.1) it was stated that on every Einstein manifold \((M,g)\), \(n \ge 4\), the following identity is satisfied:
The remarks above lead to the problem of investigation of curvature properties of non-Einstein and non-conformally flat semi-Riemannian manifolds \((M,g)\), \(n \ge 4\), satisfying at every point of \(M\) the curvature condition, of the following form: the difference tensor \(R\cdot C - C \cdot R\) is proportional to \(Q(g,R)\), \(Q(S,R)\), \(Q(g,C)\) and \(Q(S,C)\). Such conditions are strongly related to some pseudosymmetry type curvature conditions, see, e.g., [2] and references therein. In Sect. 2 we present the definitions of the most important conditions of pseudosymmetry type. For instance, (1.2) and (1.3) are conditions of this kind. We also note that there are manifolds for which the difference tensor \(R\cdot C - C \cdot R\) is a linear combination of the Tachibana tensors above, see, e.g., Sect. 5 of the present paper, [12](Theorem 5.1) and [13](Propositions 2.1 and 3.2).
In this paper we will investigate semi-Riemannian manifolds \((M,g)\), \(n \ge 4\), satisfying at every point of \(M\) the following condition:
It is obvious that \((*)\) is satisfied at every point of \(M\) at which \(C\) vanishes. It is also clear that (1.8) and (1.9) imply that
holds on any Einstein manifold \((M,g)\), \(n \ge 4\). Therefore we will restrict our considerations to manifolds \((M,g)\), \(n \ge 4\), satisfying \((*)\) on the set \({\mathcal U} = {\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\). We will investigate on \({\mathcal U}\) the condition
where \(L\) is some function on this set. We mention that if the tensor \(R\cdot C - C \cdot R\) vanishes on \({\mathcal U}\), then on this set we have ([11] Theorem 4.1)
On the other hand, if \(Q(S,C)\) vanishes on \({\mathcal U}\) then at every point \(x \in {\mathcal U}\) we have: (i) if \(\text{ rank }\, S = 1\) at \(x\) then \(\kappa = 0\) and (1.11) hold at \(x\) (see Sect. 3) or (ii) if \(\text{ rank }\, S > 1\) at \(x\) then \(C \cdot R = 0\) and \(R\cdot C =\frac{\kappa }{n-1}\, Q(g,C)\) hold at \(x\) (see Sect. 4). Thus we see that in the case (ii), if a manifold satisfies \((*)\) then its scalar curvature must vanish on \({\mathcal U}\).
The main result of Sect. 3 (Theorem 3.4) states that pseudosymmetric manifolds satisfying some additional curvature conditions are quasi-Einstein manifolds satisfying the conditions: \(C \cdot C = 0\), \(C \cdot R = 0\) and (1.10) with the function \(L = \frac{1}{n-1}\). In that section an example of warped product manifolds satisfying assumptions of Theorem 3.4 is also given.
The main result of Sect. 4 states that every essentially conformally symmetric manifold (e.c.s. manifold) satisfies \(R \cdot C = C \cdot R = Q(S,C) = 0\). We refer to [14–17] for recent results on e.c.s. manifolds. We also mention that some e.c.s. metrics are realized on compact manifolds ([15, 17]).
In Sect. 5 Roter type manifolds satisfying (1.10) are investigated. We prove (Theorem 5.2) that if \((M,g)\), \(n \ge 4\), is a Roter type manifold with vanishing scalar curvature \(\kappa \) on \({\mathcal U} \subset M\) then (1.10), with \(L= - 1\), holds on this set. In Theorem 5.3 we present some converse statement. We show (Example 5.4) that under some conditions the Cartesian product of two semi-Riemannian spaces of constant curvature satisfies assumptions of Theorem 5.3.
2 Preliminaries
Throughout this paper, all manifolds are assumed to be connected paracompact manifolds of class \(C^{\infty }\). Let \((M,g)\) be an \(n\)-dimensional, \(n \ge 3\), semi-Riemannian manifold, let \(\nabla \) be its Levi–Civita connection and \(\mathfrak {X}(M)\) the Lie algebra of vector fields on \(M\). We define on \(M\) the endomorphisms \(X \wedge _{A} Y\) and \({\mathcal {R}}(X,Y)\) of \(\mathfrak {X}(M)\) by
and
respectively, where \(A\) is a symmetric \((0,2)\)-tensor on \(M\) and \(X, Y, Z \in \mathfrak {X}(M)\). The Ricci tensor \(S\), the Ricci operator \({\mathcal {S}}\) and the scalar curvature \(\kappa \) of \((M,g)\) are defined by \(S(X,Y)= tr \{ Z \rightarrow {\mathcal {R}}(Z,X)Y \}\), \(g({\mathcal S}X,Y)= S(X,Y)\) and \(\kappa = tr\, {\mathcal {S}}\), respectively. The endomorphism \({\mathcal {C}}(X,Y)\) is given by
Finally, the \((0,4)\)-tensor \(G\), the Riemann–Christoffel curvature tensor \(R\) and the Weyl conformal curvature tensor \(C\) of \((M,g)\) are defined by
respectively, where \(X_1,X_2,\ldots \in \mathfrak {X}(M)\).
Let \({\mathcal B}\) be a tensor field sending any \(X, Y \in \mathfrak {X}(M)\) to a skew-symmetric endomorphism \({\mathcal B}(X,Y)\), and let \(B\) be a \((0,4)\)-tensor associated with \({\mathcal B}\) by
It is well-known that the tensor \(B\) is said to be a generalized curvature tensor if the following conditions are fulfilled: \(B(X_1,X_2,X_3,X_4) = B(X_3,X_4,X_1,X_2)\) and
For \({\mathcal B}\) as above, let \(B\) be again defined by (2.1). We extend the endomorphism \({\mathcal B}(X,Y)\) to a derivation \({\mathcal B}(X,Y) \cdot \, \) of the algebra of tensor fields on \(M\), requiring that it commutes with contractions and \(\ {\mathcal B}(X,Y) \cdot \, f = 0\) for any smooth function \(f\) on \(M\). Now for a \((0,k)\)-tensor field \(T\), \(k \ge 1\), we can define the \((0,k+2)\)-tensor \(B \cdot T\) by
If \(A\) is a symmetric \((0,2)\)-tensor then we define the \((0,k+2)\)-tensor \(Q(A,T)\) by
In this manner we obtain the \((0,6)\)-tensors \(B \cdot B\) and \(Q(A,B)\). Substituting \({\mathcal {B}} = {\mathcal {R}}\) or \({\mathcal {B}} = {\mathcal {C}}\), \(T=R\) or \(T=C\) or \(T=S\), \(A=g\) or \(A=S\) in the above formulas, we get the tensors \(R\cdot R\), \(R\cdot C\), \(C\cdot R\), \(R\cdot S\), \(Q(g,R)\), \(Q(S,R)\), \(Q(g,C)\) and \(Q(g,S)\).
For a symmetric \((0,2)\)-tensor \(E\) and a \((0,k)\)-tensor \(T\), \(k \ge 2\), we define their Kulkarni–Nomizu product \(E \wedge T\) by
see [18]. The tensor \(E \wedge T\) will be called the Kulkarni–Nomizu tensor of \(E\) and \(T\). The following tensors are generalized curvature tensors: \(R\), \(C\) and \(E \wedge F\), where \(E\) and \(F\) are symmetric \((0,2)\)-tensors. We have \(\, G= \frac{1}{2}\, g \wedge g\) and
For symmetric \((0,2)\)-tensors \(E\) and \(F\) we have (see, e.g., [19] Sect. 3)
We also have (cf. [18] eq. (3))
For a symmetric \((0,2)\)-tensor \(A\) we denote by \({\mathcal {A}}\) the endomorphism related to \(A\) by \(g({\mathcal {A}}X,Y)= A(X,Y)\). The tensor \(A^{p}\), \(p \ge 2\), is defined by \(A^{p}(X,Y) = A^{p-1} ({\mathcal {A}}X, Y)\). Further, let \(T\) be a \((0,k)\)-tensor, \(k \ge 2\). We will call the tensor \(Q(A,T)\) the Tachibana tensor of \(A\) and \(T\), or the Tachibana tensor for short (see, e.g., [8]). By an application of (2.3) we obtain on \(M\) the identities
From the tensors \(g\), \(R\) and \(S\) we define the following \((0,6)\)-Tachibana tensors: \(Q(S,R)\), \(Q(g,R)\), \(Q(g,g \wedge S)\) and \(Q(S, g \wedge S)\). Using (2.3) we can check that the other \((0,6)\)-Tachibana tensors that are constructed from \(g\), \(R\) and \(S\) may be expressed by the four Tachibana tensors above or they vanish identically on \(M\).
Proposition 2.1
([20] Proposition 4.1, [21] Lemma 3.4) Let \((M,g)\), \(n \ge 3\), be a semi-Riemannian manifold. Let a non-zero symmetric \((0,2)\)-tensor \(A\) and a generalized curvature tensor \(B\), defined at \(x \in M\), satisfy at this point \(Q(A,B) = 0\). In addition, let \(Y\) be a vector at \(x\) such that the scalar \(\rho = w(Y)\) is non-zero, where \(w\) is a covector defined by \(w(X) = A(X,Y)\), \(X \in T_{x}M\). Then we have
-
(i)
\(A - \rho \, w \otimes w \ne 0\) and \(B = \lambda \, A \wedge A\), \(\lambda \in {\mathbb R}\), or (ii) \(A = \rho \, w \otimes w\) and
$$\begin{aligned}&w(X)\, B(Y,Z, X_{1}, X_{2}) + w(Y)\, B(Z,X, X_{1}, X_{2}) \nonumber \\&\quad +\, w(Z)\, B(X,Y, X_{1}, X_{2}) = 0,\quad X,Y,Z,X_{1},X_{2} \in T_{x}M. \end{aligned}$$(2.5)Moreover, in both cases the following condition holds at \(x\):
$$\begin{aligned} B \cdot B&= Q(Ric(B),B). \end{aligned}$$
3 Some special generalized curvature tensors
Let \(e_{1}, e_{2}, \ldots , e_{n}\) be an orthonormal basis of \(T_{x}M\) at a point \(x \in M\) of a semi-Riemannian manifold \((M,g)\), \(n \ge 3\), and let \(g( e_{j}, e_{k}) = \varepsilon _{j} \delta _{jk}\), where \(\varepsilon _{j} = \pm 1\) and \(h,i,j,k,l,m, r,s \in \{ 1, 2, \ldots , n \}\). For a generalized curvature tensor \(B\) on \(M\) we denote by \(Ric(B)\), \(\kappa (B)\) and \(Weyl(B)\) its Ricci tensor, scalar curvature and Weyl tensor, respectively. We have
and we write \({\mathcal {U}}_{Ric(B)} := \{x \in M\, | \, Ric(B) - \frac{\kappa (B) }{n}\, g \ne 0\ \text{ at }\ x \}\) and \({\mathcal {U}}_{Weyl(B)} := \{x \in M\, | \, Weyl(B) \ne 0\ \text{ at }\ x \}\).
Let \(B_{hijk}\), \(T_{hijk}\) and \(A_{ij}\) be the local components of the generalized curvature tensors \(B\) and \(T\) and a symmetric \((0,2)\)-tensor \(A\) on \(M\), respectively. The local components \((B \cdot T)_{hijklm}\) and \(Q(A,T)_{hijklm}\) of the tensors \(B \cdot T\) and \(Q(A,T)\) are the following:
If we contract the last equation with \(g^{ij}\) and \(g^{hm}\), then we obtain
Proposition 3.1
([22] Proposition 2.1) Let \(B\) be a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\). If
on \({\mathcal {U}}_{Weyl (B)} \subset M\), where \(L\) is a function on \({\mathcal {U}}_{Weyl (B)}\), and \(Ric(B)_{ij}\) and \(B_{hijk}\) are the local components of \(Ric(B)\) and \(B\), respectively, then at every point of \({\mathcal {U}}_{Weyl (B)}\) we have
Let \(B\) be a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\). The local components \((B \cdot Weyl(B))_{hijklm}\) and \((Weyl(B) \cdot B)_{hijklm}\) of the tensors \(B \cdot Weyl(B)\) and \(Weyl(B) \cdot B\) are the following:
Using (3.1), (3.5) and (3.6) we can check that the local components \((B \cdot Weyl(B) - Weyl(B) \cdot B)_{hijklm}\) of the difference tensor \(B \cdot Weyl(B) - Weyl(B) \cdot B\) can be expressed as follows:
where \(V_{mijk} = g^{rs} Ric(B)_{mr}B_{sijk}\) (see [2, 11, 12]).
According to [9], a generalized curvature tensor \(B\) on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), is called a Roter type tensor if
on \({\mathcal {U}}_{Ric(B)} \cap {\mathcal {U}}_{Weyl (B)}\), where \(\phi \), \(\mu \) and \(\eta \) are some functions on this set. Manifolds admitting Roter type tensors were investigated (e.g.) in [23]. We have
Proposition 3.2
Let \(B\) be a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), satisfying (3.7) on \({\mathcal {U}} = {\mathcal {U}}_{Ric(B)} \cap {\mathcal {U}}_{Weyl (B)} \subset M\). Then the following relations hold on \({\mathcal {U}}\):
-
(i)
$$\begin{aligned}&(Ric(B))^{2} = \alpha _{1}\, Ric(B) + \alpha _{2} \, g,\nonumber \\&\alpha _{1} = \kappa (B) + \phi ^{-1} ( (n-2)\mu -1 ),\quad \alpha _{2} =\phi ^{-1} ( \mu \kappa (B) + (n-1) \eta ) , \end{aligned}$$(3.8)$$\begin{aligned}&(\mathrm{a})\quad B \cdot B = L_{B}\, Q(g,B), \quad L_{B} = \phi ^{-1} \left( (n-2) (\mu ^{2} - \phi \eta ) - \mu \right) ,\nonumber \\&(\mathrm{b})\quad B \cdot Weyl(B) = L_{B}\, Q(g,Weyl(B)),\nonumber \\&(\mathrm{c})\quad B \cdot B = Q(Ric(B),B) + (L_{B} + \phi ^{-1} \mu ) \, Q(g,{ Weyl}(B)),\end{aligned}$$(3.9)$$\begin{aligned}&{ Weyl}(B) \cdot B = L_{{ Weyl}(B)}\, Q(g,B) ,\quad L_{{ Weyl}(B)} = L_{B} + \frac{1}{n-2} \left( \frac{\kappa (B) }{n-1} - \alpha _{1}\right) ,\nonumber \\ \end{aligned}$$(3.10)$$\begin{aligned}&{ Weyl}(B) \cdot { Weyl}(B) = L_{{ Weyl}(B)}\, Q(g,{ Weyl}(B)) ,\end{aligned}$$(3.11)$$\begin{aligned}&{ Weyl}(B) \cdot B = Q(Ric(B), Weyl(B))\nonumber \\&\quad +\, \left( L_{B} - \frac{\kappa (B)}{n-1} \right) Q(g,Weyl(B)). \end{aligned}$$(3.12)
We also have
$$\begin{aligned}&B \cdot { Weyl}(B) - { Weyl}(B) \cdot B = \left( \frac{(n-1) \mu - 1}{(n-2) \phi } + \frac{\kappa (B) }{n-1} \right) Q(g,B)\nonumber \\&\quad +\, \frac{1}{n-2}\, Q(Ric(B),B) + \frac{\mu ((n-1) \mu - 1) - (n-1) \phi \eta }{(n-2) \phi } \, Q(Ric(B),G) , \end{aligned}$$and, equivalently,
$$\begin{aligned} B \cdot Weyl(B) \!-\! Weyl(B) \cdot B&= \left( \phi ^{-1} \left( \mu \!-\! \frac{1}{n-2}\right) \!+\! \frac{\kappa (B) }{n-1} \right) Q(g,B)\nonumber \\&\quad +\, \left( \! \phi ^{-1} \mu \left( \! \mu \!-\! \frac{1}{n\!-\!2}\right) \!-\! \eta \right) Q(Ric(B),G) \quad \quad \quad \quad \quad \end{aligned}$$(3.13)([23] Sects. 1 and 4).
-
(ii)
$$\begin{aligned} Q(Ric(B),{ Weyl}(B))&= \phi ^{- 1} \left( \frac{1}{n-2} - \mu \right) \, Q(g,B)\nonumber \\&+\,\frac{1}{n-2}\, \left( L_{B} - \frac{\kappa (B) }{n-1}\right) \, Q(g, g \wedge Ric(B)). \end{aligned}$$(3.14)
Moreover, if \(L_{B} = \frac{ \kappa (B) }{n-1}\), resp., \(\kappa (B) =\, 0\), then we have
$$\begin{aligned} Q(Ric(B),{ Weyl}(B))&= L_{Weyl(B)}\, Q(g,B) , \end{aligned}$$(3.15)and
$$\begin{aligned} B \cdot { Weyl}(B) - { Weyl}(B) \cdot B&= - Q(Ric(B),Weyl(B)) , \end{aligned}$$(3.16)respectively.
-
(iii)
If \(L_{{ Weyl}(B)}= 0\) on \({\mathcal {U}}_{1} \subset {\mathcal {U}}\) then on this set we have
$$\begin{aligned}&\phi ^{-1} \left( \frac{1}{n-2} - \mu \right) \,( B \cdot { Weyl}(B) - { Weyl}(B) \cdot B)\nonumber \\&\quad = (n-2) \left( \phi ^{-1} \mu \left( \mu - \frac{1}{n-2} \right) - \eta \right) Q(Ric(B), Weyl(B)) . \end{aligned}$$(3.17)
Proof
(ii) Using (3.1), (2.4), (3.7) and suitable formulas of (i) we get
which leads to (3.14).
If \(L_{B} = \frac{ \kappa (B) }{n-1}\) then, (3.12) reduces to (3.15). It is clear that (3.15) also follows from (3.18).
If \(\kappa (B) = 0\), then (3.9)(b) and (3.12) yield (3.16). We can also obtain (3.16) from (3.13), by making use of (2.3), (3.9)(a) and (3.14).
(iii) Conditions (3.8), (3.9)(a) and (3.10) yield
Now (3.13) turns into
Further, (3.10) yields \(\, L_{B} - \frac{\kappa (B)}{n-1}= \phi ^{-1} ( \mu - \frac{1}{n-2})\), hence (3.14) takes the form
which together with (3.19) gives (3.17). Our proposition is thus proved. \(\square \)
Proposition 3.3
Let \(B\) be a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\). If the conditions
are satisfied on \({\mathcal U} = {\mathcal U}_{Ric(B)} \cap {\mathcal U}_{Weyl(B)} \subset M\), then on this set we have
and the tensor \(Weyl(B)\) satisfies (2.5) for some non-zero covector \(w\).
Proof
First of all we note that (3.20) yields
Next, comparing the right-hand sides of (3.22) and (3.27) we obtain
From this, in view of Proposition 4.1 of [20] (see also [21] Lemma 3.4), we get
Since \(Ric(Weyl(B)) = 0\), (3.29) reduces to (3.23).
Suppose that \(\text{ rank }\, (Ric(B) - \frac{\kappa (B)}{n}\, g) > 1\) at \(x \in {\mathcal U}\). From (3.28), in view of Proposition 4.1 of [20] (see also [21] Lemma 3.4 or [24] Lemma 3.1), it follows that
at \(x\), where \(\phi \in \mathbb {R} \setminus \{ 0 \}\). Applying (3.1) in (3.30) we immediately get
This, together with (3.9) and (3.20), yields
Comparing the right-hand sides of (3.21) and (3.31) we get \(Q(g, Weyl(B)) = 0\), and, as a consequence, \(Weyl(B) = 0\), which is a contradiction. Therefore (3.24) holds on \({\mathcal U}\). Thus from (3.28), in view of Proposition 2.1 (ii), it follows that the tensor \(Weyl(B)\) satisfies (2.5) for some non-zero covector \(w\). Further, we note that (3.24) is equivalent to
(cf. [25] eq. (21)). Now from (3.28), by making use of (2.3), (3.1) and (3.32), we obtain
In terms of tensor components,
Contracting this with \(g^{rs}\) and using (3.3), (3.4) and (3.32) in the form
Applying this, (3.1), (3.33) and (3.20) in the form
to the identity (3.6), we obtain (3.25). Finally, (3.22) and (3.25) give (3.26), which completes the proof. \(\square \)
As an immediate consequence of Proposition 3.3 we have
Theorem 3.4
Let \((M,g)\), \(n \ge 4\), be a semi-Riemannian manifold. If the following conditions
are satisfied on \({\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\), then on this set we have
Proposition 3.5
Let \(B\) be a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), satisfying at every point \(x \in {\mathcal {U}} = {\mathcal {U}}_{Ric(B)} \cap {\mathcal {U}}_{Weyl (B)} \subset M\) the conditions
Then (3.20), (3.21), (3.22) and (3.24) hold on \({\mathcal {U}}\). Moreover, the scalar curvature \(\kappa (B)\) is non-zero at every point of \({\mathcal {U}}\).
Proof
We can easily adopt the proof of Theorem 4.2 of [26] to verify our proposition. \(\square \)
As an immediate consequence of Propositions 3.3 and 3.6 we get
Proposition 3.6
If \(B\) is a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), satisfying (3.39) and (3.40) on \({\mathcal {U}}_{Ric(B)} \cap {\mathcal {U}}_{Weyl (B)} \subset M\), then (3.25) and (3.26) hold on this set.
This proposition implies
Theorem 3.7
If the Ricci tensor \(S\) and the Weyl tensor \(C\) of a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), satisfy (3.39) and (3.40) on \({\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\), then (3.36), (3.37), and, as a consequence, (3.38) hold on this set.
Example 3.8
-
(i)
Let \(\overline{M} \times _{F} \widetilde{N}\) be the warped product of an \(1\)-dimensional manifold \((\overline{M},\overline{g})\), with \(\overline{g} = \varepsilon = \pm 1\), a warping function \(F\) given by \(F(x^{1}) = a\, \exp (b x^{1})\), \(a = const. > 0\), \(b = const. \ne 0\), and an \((n-1)\)-dimensional fibre \((\widetilde{N}, \widetilde{g})\), \(n \ge 4\).
-
(ii)
Proposition 4.2 of [27] states that the above defined warped product \(\overline{M} \times _{F} \widetilde{N}\): such that the fibre \((\widetilde{N}, \widetilde{g})\) is a conformally flat semi-Riemannian manifold with \(\text{ rank }\, \widetilde{S} = 1\) and the vanishing scalar curvature \(\widetilde{\kappa }\) satisfies (3.34)–(3.36). We note that the scalar curvature \(\kappa \) of \(\overline{M} \times _{F} \widetilde{N}\) is a non-zero constant. Precisely, we have ([27] Eq. (28))
$$\begin{aligned} \kappa&= - \frac{(n-1)n}{4} \varepsilon a^{2} . \end{aligned}$$(3.41)An example of a family of such warped products is given in Example 4.1 of [27].
-
(iii)
Let now the fibre \((\widetilde{N}, \widetilde{g})\) be the semisymmetric manifold defined in Example 4.1 of [19]. This manifold satisfies \(\text{ rank }\, \widetilde{S} = 1\) and \(\widetilde{\kappa } = 0\). The scalar curvature \(\kappa \) of \(\overline{M} \times _{F} \widetilde{N}\) satisfies (3.41) ([24] Eq. (54)). Moreover, the warped product \(\overline{M} \times _{F} \widetilde{N}\) satisfies (3.34)–(3.36) ([24] Example 5.1, [2] Sect. 6 pp. 15–16). As it was stated in [24] (Example 5.4), the manifold \(\overline{M} \times _{F} \widetilde{N}\) can be locally realized as a hypersurface in a semi-Riemannian space of non-zero constant curvature.
Proposition 3.9
Let \(B\) be a generalized curvature tensor on a semi-Riemannian manifold \((M,g)\), \(n \ge 4\).
-
(i)
If the conditions
$$\begin{aligned} Q(Ric(B),B)&= 0 ,\end{aligned}$$(3.42)$$\begin{aligned} \text{ rank }\,( Ric(B) )&= 1 \end{aligned}$$(3.43)are satisfied on \({\mathcal U} = {\mathcal U}_{Ric(B)} \cap {\mathcal U}_{Weyl(B)} \subset M\), then on this set we have
$$\begin{aligned}&\kappa (B) = 0,\end{aligned}$$(3.44)$$\begin{aligned}&B \cdot { Weyl}(B) = { Weyl} (B) \cdot B = Q(Ric(B), { Weyl}(B)) = 0 . \end{aligned}$$(3.45) -
(ii)
If the conditions (3.43) and
$$\begin{aligned} Q(Ric(B),Weyl(B) )&= 0 \end{aligned}$$(3.46)are satisfied on \({\mathcal U} = {\mathcal U}_{Ric(B)} \cap {\mathcal U}_{Weyl(B)} \subset M\), then on this set we have (3.44) and
$$\begin{aligned} B \cdot Weyl(B)&= Weyl (B) \cdot B = 0 . \end{aligned}$$
Proof
Let \(B_{hijk}\), \(Ric(B)_{ij}\) and \(Weyl(B)_{hijk}\) be the local components of the tensors \(B\), \(Ric(B)\) and \(Weyl(B)\) at \(x \in {\mathcal U}\), respectively.
-
(i)
By (3.43), at \(x\) we have \(Ric(B) = \rho \, w \otimes w\) and \(Ric(B)_{ij} = \rho \, w_{i} w_{j}\), where \(w_{i}\) are the components of the covector \(w\). Since (3.42) and (3.43) hold at \(x\), (2.5) yields
$$\begin{aligned} w_{h}B_{ijkl} + w_{i}B_{jhkl} + w_{j}B_{hikl}&= 0 . \end{aligned}$$(3.47)Contracting this with \(g^{hl}\) and using (3.43) we get
$$\begin{aligned} w^{r}B_{ijkr}&= 0, \quad w^{r} = g^{rs}w_{s} . \end{aligned}$$(3.48)Transvecting now (3.47) with \(w^{h}\) and using (3.48) we get (3.44). Now (3.42)-(3.44), together with (2.3) and (3.1), yield
$$\begin{aligned}&Q(Ric(B), { Weyl}(B)) =Q( Ric(B), B) - \frac{1}{n-2}\, Q( Ric(B), g \wedge Ric(B))\nonumber \\&\quad =Q( Ric(B), B) + \frac{1}{2(n-2)}\, Q( g, Ric(B) \wedge Ric(B))=Q( Ric(B), B) = 0. \end{aligned}$$Further, in view of Proposition 2.1, (3.42) yields \(B \cdot B = Q(Ric(B),B)\), and, consequently, \(B \cdot B = 0\), which implies \(B \cdot Weyl(B) = 0\). Now, Proposition 3.3 completes the proof of (i).
-
(ii)
Since (3.46) and (3.43) hold at \(x\), (2.5) yields
$$\begin{aligned} w_{h}{ Weyl}(B)_{ijkl} + w_{i}{ Weyl}(B)_{jhkl} + w_{j}{ Weyl}(B)_{hikl}&= 0 . \end{aligned}$$(3.49)Contracting this with \(g^{hl}\) we get
$$\begin{aligned} w^{r}Weyl(B)_{ijkr}&= 0, \quad w^{r} = g^{rs}w_{s} . \end{aligned}$$(3.50)Transvecting (3.49) with \(w^{h}\) and using (3.50) we get (3.44). Next, by making use of (2.3), (3.1), (3.43), (3.44) and (3.46), we get
$$\begin{aligned} 0&= Q(Ric(B), { Weyl}(B))=Q( Ric(B), B) - \frac{1}{n-2}\, Q( Ric(B), g \wedge Ric(B))\\&= Q( Ric(B), B) + \frac{1}{2(n-2)}\, Q( g, Ric(B) \wedge Ric(B)) = Q( Ric(B), B) . \end{aligned}$$Now (i) completes the proof of (ii).
\(\square \)
Example 3.10
-
(i)
Let \(\overline{M} \times _{F} \widetilde{N}\) be the warped product of a \(3\)-dimensional manifold \((\overline{M},\overline{g})\), with a warping function \(F\) and a \(1\)-dimensional fibre \((\widetilde{N}, \widetilde{g})\). In Proposition 3.3(i) of [28] it was proved that if the conditions
$$\begin{aligned} \kappa = 0 ,&S^{2} = 0 , \end{aligned}$$(3.51)are satisfied on \(\overline{M} \times _{F} \widetilde{N}\), then \(\text{ rank }\, S \le 1\). In addition, if
$$\begin{aligned} S \cdot C= 0,&R \cdot R = Q(S,R) \end{aligned}$$(3.52)on \(\overline{M} \times _{F} \widetilde{N}\), then it is a semisymmetric manifold ([28], Proposition 3.3(ii)). Thus, by (3.52), on \(\overline{M} \times _{F} \widetilde{N}\) we have \(Q(S,R) = 0\). Now, in view of Proposition 3.6(i),
$$\begin{aligned} R \cdot C = C \cdot R&= Q(S,C) = 0 \end{aligned}$$(3.53)on \({\mathcal U}_{S} \cap {\mathcal U}_{C} \subset \overline{M} \times _{F} \widetilde{N}\).
-
(ii)
In Sect. 4 of [28] a class of warped products \(\overline{M} \times _{F} \widetilde{N}\) of dimension \(\ge 4\) were investigated. Among others, in this class of warped products there are manifolds satisfying (3.51)-(3.53).
4 Manifolds with parallel Weyl conformal curvature tensor
Let \((M,g)\), \(n \ge 4\), be a semi-Riemannian manifold whose Weyl conformal curvature tensor is parallel, i.e., \(\nabla C = 0\) on \(M\). It is obvious that the last condition implies \(R \cdot C = 0\). Suppose, moreover, that the manifold \((M,g)\) is neither conformally flat nor locally symmetric. Such manifolds are called essentially conformally symmetric manifolds, e.c.s. manifolds, in short (see, e.g., [29] and [30]). E.c.s. manifolds are semisymmetric manifolds (\(R \cdot R = 0\), [29] Theorem 9) satisfying \(\kappa = 0\) and \(Q(S,C) = 0\) ([29] Theorems 7 and 8). In addition,
holds on \(M\), where \(F\) is some function on \(M\), called the fundamental function ([30]). At every point of \(M\) we also have \(\text{ rank }\, S \le 2\) ([30] Theorem 5). We mention that the local structure of e.c.s. manifolds has already been described. We refer to [14] and [16] for the final results related to this subject. We also mention that certain e.c.s. metrics are realized on compact manifolds ([15, 17]).
Suppose that \(F = 0\) at \(x \in M\). Now (4.1) implies \(\text{ rank }\, S \le 1\) at \(x\). It is clear that if \(S\) vanishes, then (3.53) holds at \(x\). If \(\text{ rank }\, S = 1\), then in view Proposition 3.9(ii) we also have (3.53) at \(x\). Next, we assume that \(F\) is non-zero at \(x \in M\). Then \(\text{ rank }\, S = 2\) at \(x\). In this case (4.1) turns into (3.7) with \(B= R\), \(Ric(B)= S\), \(\phi = F^{-1}\), \(\mu = \frac{1}{n-2}\) and \(\eta = 0\). Therefore (3.10) and (3.11) reduce to \(C \cdot R = 0\) and \(C \cdot C = 0\), respectively. Consequently, (3.53) holds at \(x\). Thus we have proved the following
Theorem 4.1
Condition (3.53) is satisfied on every essentially conformally symmetric manifold \((M,g)\).
Remark 4.2
5 Roter type manifolds satisfying (1.10)
We recall that if the curvature tensor \(R\) of a semi-Riemannian manifold \((M,g)\), \(n \ge 4\), is a linear combination of the Kulkarni–Nomizu products \(S \wedge S\), \(g \wedge S\) and \(G = \frac{1}{2}\, g \wedge g\) on \({\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\), i.e., (1.7) holds on this set, then \((M,g)\) is called a Roter type manifold. Such manifolds were investigated among others in [32] and [33]. We also refer to [10] for a survey on Roter type manifolds, as well as on Roter type hypersurfaces. Curvature properties of manifolds satisfying (1.7) are presented in Proposition 3.2 (for \(B = R\)).
Remark 5.1
([11] Theorem 4.1 and Corollary 4.1) Let \((M,g)\), \(n \ge 4\), be a semi-Riemannian manifold and let \({\mathcal U} = {\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\). If \(R \cdot C - C \cdot R = L\, Q(g,C)\) holds on \({\mathcal U}\) for some function \(L\), then \(R \cdot R = L\, Q(g,R)\) and \(C \cdot R = 0\) on this set. In particular, if \(R \cdot C = C \cdot R\) holds on \({\mathcal U}\), then \(R \cdot R = R \cdot C = C \cdot R = 0\) on this set. Therefore we consider manifolds satisfying (1.10) and (1.7) on \({\mathcal U}\) with non-zero function \(L\).
As an immediate consequece of Proposition 3.2(ii) we get
Theorem 5.2
Let \((M,g)\), \(n \ge 4\), be a a semi-Riemannian manifold satisfying (1.7) on \({\mathcal U} = {\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\). If \(\kappa = 0\) on \({\mathcal U}\) then (1.10), with \(L= - 1\), holds on this set.
We also have a converse to this result.
Theorem 5.3
Let \((M,g)\), \(n \ge 4\), be a semi-Riemannian manifold satisfying (1.10) and (1.7) on \({\mathcal U} = {\mathcal U}_{S} \cap {\mathcal U}_{C} \subset M\), and let \({\mathcal U}_{1} \subset {\mathcal U}\) be the set of all points at which the functions \(L\) and \(L_{C}\), defined by (1.10), (3.10) and (3.11) (for \(B = R\)), respectively, are nowhere zero on this set. Then on \({\mathcal U}_{1}\) we have
Proof
From (3.9)(b) and (3.10) we obtain on \({\mathcal U}\)
This, together with (1.10), yields
which, via (2.3), turns into
We restrict our considerations to the set \({\mathcal U}_{1}\). Now the last equation turns into
and
We note that if we had \(\text{ rank }\, (S + (L_{C} - L_{R}) L^{-1} \, g ) = 1\) at a point of \({\mathcal U}_{1}\) then - in a standard way - we would obtain \(C = 0\) from (1.7), which is a contradiction. Therefore (5.3) implies ([20] Proposition 4.1, [21] Lemma 3.4): \(\text{ rank }\, (S + (L_{C} - L_{R}) L^{-1} \, g ) \ge 2\) and
on \({\mathcal U}_{1}\), where \(\lambda \) is a function on this set. Now (5.4), via (2.2), turns into
The decomposition of \(R\) is unique on \({\mathcal U}_{1}\) (see, e.g., [24] Lemma 3.1). Therefore (1.7) and (5.6) yield \(\phi = \lambda \) and
Since \(L_{C} - L_{R} = \frac{1}{n-2} ( \phi ^{-1} ( 1 - (n-2) \mu ) - \frac{n-2}{n-1} \kappa )\), (5.7)(a) can be written as
On the other hand, we have
which, together with (5.5), gives \(C \cdot C = - L_{C} L^{-1}\, Q(g,C)\). From the last relation, via (3.11), it follows that
on \({\mathcal U}_{1}\). Now from (5.8) and (5.9) we conclude that (5.1) and (5.2) are satisfied on this set, which completes the proof. \(\square \)
Example 5.4
-
(i)
Let \((M,g) = N^{p}_{s_{1}}(c_{1}) \times N^{n-p}_{s_{2}}(c_{2})\) be a Cartesian product of semi-Riemannian spaces of constant curvature, where \(2 \le p \le n-2\), \(c_{1}= \frac{\kappa _{1}}{(p-1) p}\), \(c_{2}= \frac{\kappa _{2}}{(n-p-1) (n-p)}\), \(\kappa _{1}\) and \(\kappa _{2}\) are the scalar curvatures of \(N^{p}_{s_{1}}(c_{1})\) and \(N^{n-p}_{s_{2}}(c_{2})\), respectively. For the scalar curvature \(\kappa \) of \((M,g)\) we have
$$\begin{aligned} \kappa&= \kappa _{1} + \kappa _{2} = p (p-1)\, c_{1} + (n-p)(n-p-1)\, c_{2} . \end{aligned}$$(5.10)It is well-known that (3.9), with \(L_{R} = 0\), holds on \(M\) ([3] Theorem 4.5). Moreover, (3.11) is satisfied on \(M\), with
$$\begin{aligned} L_{C}&= - \frac{ (p-1) (n-p-1)}{(n-2)(n-1)}\, (c_{1} + c_{2}) \end{aligned}$$(5.11)([34] Sect. 4).
-
(ii)
We assume that \(c_{1}\) and \(c_{2}\) satisfy
$$\begin{aligned} (a)\quad c_{1} + c_{2} \ne 0\quad \text{ and } \quad (b)\quad (p-1)\, c_{1} - (n-p-1)\, c_{2} \ne 0 . \end{aligned}$$(5.12)Then \((M,g)\) is a non-conformally flat and non-Einstein manifold. More precisely, we have \({\mathcal U}_{S} \cap {\mathcal U}_{C} = M\) (cf. [35] Sect. 3). Moreover, as it was stated in Sect. 3 of [35], (3.7) holds on \(M\) with
$$\begin{aligned} \phi&= \tau \, (c_{1} + c_{2}) , \quad \eta = \tau \, c_{1}c_{2}\, ((p-1)^{2} c_{1} + (n-p-1)^{2} c_{2} ) ,\nonumber \\ \mu&= - (n-2) \tau \, c_{1}c_{2} ,\quad \tau = ( (p-1) c_{1} - (n-p-1) c_{2} )^{-2} . \end{aligned}$$(5.13) -
(iii)
In addition, we assume that \(n \ne 2 p\), \(\kappa = 0\) and \(c_{1} \ne 0\) hold on \(M\). Now (5.10) reduces to \(c_{2} = - \frac{p (p-1)}{(n-p)(n-p-1)}\, c_{1}\). Applying this in (5.11), (5.12) and (5.13) we obtain
$$\begin{aligned} c_{1} + c_{2}&= \frac{(n-1) (n-2p)}{ (n - p) (n-p-1) }\, c_{1} , \quad (p-1)\, c_{1} - (n-p-1)\, c_{2} = \frac{n (p - 1)}{n - p}\, c_{1} ,\\ \phi&= \frac{(n-1) (n-p) (n-2p)}{ n^{2} (n-p-1) (p-1)^{2} }\, c_{1}^{-1} , \quad \mu = \frac{ (n-2) p (n-p) }{ n^{2} (n-p-1) (p-1)} ,\\ \eta&= \frac{ (n-2p) p }{ n^{2} (n-p-1)} \, c_{1} , \quad L_{C} = - \frac{(p-1) (n-2p)}{ (n - 2) (n-p) }\, c_{1} . \end{aligned}$$Thus we see that \((M,g)\) is a Roter type manifold satisfying
$$\begin{aligned} R \cdot C - C \cdot R&= - Q(S,C) , \end{aligned}$$with the non-zero function \(L_{C}\) and zero scalar curvature \(\kappa \).
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Acknowledgments
The authors would like to thank the referee for his very helpful and detailed remarks and comments, which have significantly improved the presentation of this paper. The first named author is supported by the Université de Valenciennes et du Hainaut-Cambrésis, France. The second named author is supported by a grant of the Wrocław University of Environmental and Life Science, Poland.
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Deszcz, R., Głogowska, M., Hotloś, M. et al. On some curvature conditions of pseudosymmetry type. Period Math Hung 70, 153–170 (2015). https://doi.org/10.1007/s10998-014-0081-9
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DOI: https://doi.org/10.1007/s10998-014-0081-9
Keywords
- Einstein manifold
- Quasi-Einstein manifold
- Manifold with parallel Weyl tensor
- Roter type manifold
- Pseudosymmetric manifold
- Generalized Einstein metric condition
- Tachibana tensor