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Article

On the Betti and Tachibana Numbers of Compact Einstein Manifolds

1
Department of Mathematics, University of Haifa, Mount Carmel, Haifa 31905, Israel
2
Department of Mathematics, Russian Institute for Scientific and Technical Information of the Russian Academy of Sciences, 20, Usievicha Street, 125190 Moscow, Russia
3
Department of Data Analysis and Financial Technologies, Finance University, 49-55, Leningradsky Prospect, 125468 Moscow, Russia
*
Author to whom correspondence should be addressed.
Mathematics 2019, 7(12), 1210; https://doi.org/10.3390/math7121210
Submission received: 23 November 2019 / Revised: 6 December 2019 / Accepted: 7 December 2019 / Published: 9 December 2019
(This article belongs to the Special Issue Inequalities in Geometry and Applications)

Abstract

:
Throughout the history of the study of Einstein manifolds, researchers have sought relationships between the curvature and topology of such manifolds. In this paper, first, we prove that a compact Einstein manifold ( M , g ) with an Einstein constant α > 0 is a homological sphere when the minimum of its sectional curvatures > α / ( n + 2 ) ; in particular, ( M , g ) is a spherical space form when the minimum of its sectional curvatures > α / n . Second, we prove two propositions (similar to the above ones) for Tachibana numbers of a compact Einstein manifold with α < 0 .

1. Introduction

The study of Einstein manifolds has a long history in Riemannian geometry. Throughout the history of the study of Einstein manifolds, researchers have sought relationships between curvature and topology of such manifolds. A. Besse [1] summarized the results. We present here some interesting facts related to the classification of all compact Einstein manifolds satisfying a suitable curvature inequality, which is one of the subjects of our research.
Recall that an n-dimensional ( n 2 ) connected manifold M with a Riemannian metric g is said to be an Einstein manifold with Einstein constant α if its Ricci tensor satisfies Ric = α g ; moreover, we have α = s / n for its scalar curvature s. Therefore, any Einstein manifold of dimensions two and three is a space form (i.e., has constant sectional curvature). The study of Einstein manifolds is more complicated in dimension four and higher (see [1] (p. 44)).
An important problem in differential geometry is to determine whether a smooth manifold admits an Einstein metric. When α > 0 , the example are symmetric spaces, which include the sphere S n ( 1 ) with α = n 1 and the sectional curvature sec = 1 , the product of two spheres S n ( 1 ) × S n ( 1 ) with α = n 1 and 0 sec 1 , and the complex projective space C P m = S 2 m + 1 / S 1 with the Fubini–Study metric, α = 2 m + 2 and 1 sec 4 (see [2] (pp. 86, 118, 149–150)). Recall that if ( M , g ) is a compact Einstein manifold with curvature bounds of the type 3 n / ( 7 n 4 ) < sec 1 , then ( M , g ) is isometric to a spherical space form. This might be not the best estimate: for n = 4 the sharp bound is 1 / 4 (see [1] (p. 6)). In both these cases, the manifolds are real homology spheres (see [3] (p. XVI)). Therefore, any such manifold has the homology groups of an n-sphere; in particular, its Betti numbers are b 1 ( M ) = = b n 1 ( M ) = 0 .
One of the basic problems in Riemannian geometry was to classify Einstein four-manifolds with positive or nonnegative sectional curvature in the categories of either topology, diffeomorphism, or isometry (see, for example, [4,5,6,7]). It was conjectured that an Einstein four-manifold with α > 0 and non-negative sectional curvature must be either S 4 , C P 2 , S 2 ( 1 ) × S 2 ( 1 ) or a quotient. For example, if the maximum of the sectional curvatures of a compact Einstein four-manifold is bounded above by ( 2 / 3 ) α , or if α = 1 and the minimum of the sectional curvatures ( 1 / 6 ) ( 2 2 ) , then the manifold is isometric to S 4 , R P 4 or C P 2 (see [6]). Classification of four-dimensional complete Einstein manifolds with α > 0 and pinched sectional curvature was obtained in [7].
Here, we consider this problem from another side. Given a Riemannian manifold ( M , g ) , the notion of symmetric curvature operator R ¯ , acting on the space Λ 2 M of 2-forms, is an important invariant of a Riemannian metric (see [2] (p. 83); [8,9]). The Tachibana Theorem (see [10]) asserts that a compact Einstein manifold ( M , g ) with R ¯ > 0 is a spherical space form. Later on, it was proved that compact manifolds with R ¯ > 0 are spherical space forms (see [11]).
Denote by R the symmetric curvature operator of the second kind, acting on the space S 0 2 M of traceless symmetric two-tensors (see [1] (p. 52); [9,12]). Kashiwada (see [9]) proved that a compact Einstein manifold with R > 0 is a spherical space form. This statement is an analogue of the theorem of Tachibana in [10]. In contrast, if a complete Riemannian manifold ( M , g ) satisfies sec δ > 0 , then M is compact with diam ( M , g ) π / δ (see [2] (p. 251)).
Remark 1
(By [2] (Theorem 10.3.7)). There are manifolds with metrics of positive or nonnegative sectional curvature but not admitting any metric with R ¯ 0 (see also [2] (p. 352)). In particular, for three-dimensional manifolds the inequality sec > 0 is equivalent to the inequality R ¯ > 0 (see [9]).
Using Kashiwada’s theorem from [9] we can prove the following.
Theorem 1.
Let ( M , g ) be a compact Einstein manifold with Einstein constant α > 0 , and let δ be the minimum of its positive sectional curvature. If δ > α / n , then ( M , g ) is a spherical space form.
We can present a generalization of above result in the following form.
Theorem 2.
Let ( M , g ) be a compact Einstein manifold with Einstein constant α > 0 and let δ be the minimum of its positive sectional curvature. If δ > α / ( n + 2 ) , then ( M , g ) is a homological sphere.
Obviously, S n ( 1 ) × S n ( 1 ) is not an example for Theorem 1 because the minimum of its sectional curvature is zero and α = n 1 . On the other hand, the complex projective space C P m is an Einstein manifold with α = 2 m + 2 and sectional curvature bounded below by δ = 1 . Then the inequality α < ( n + 2 ) δ can be rewritten in the form δ > 1 because n = 2 m . Therefore, C P m is not an example for Theorem 1. Moreover, all even dimensional Riemannian manifolds with positive sectional curvature have vanishing odd-dimensional homology groups. Thus, Theorem 1 complements this statement (see [2] (p. 328)).
Let ( M , g ) be an n-dimensional compact connected Riemannian manifold. Denote by Δ ( p ) the Hodge Laplacian acting on differential p-forms on M for p = 1 , , n 1 . The spectrum of Δ ( p ) consists of an unbounded sequence of nonnegative eigenvalues which starts from zero if and only if the p-th Betti number b p ( M ) of ( M , g ) does not vanish (see [13]). The sequence of positive eigenvalues of Δ ( p ) is denoted by
0 < λ 1 ( p ) < < λ m ( p ) < .
In addition, if F p ( ω ) σ > 0 (see Equation (4) of F p ) at every point of M, then λ 1 ( p ) σ (see [13] (p. 342)). Using this and Theorem 1, we get the following.
Corollary 1.
Let ( M , g ) be a compact Einstein manifold with positive Einstein constant α and sectional curvature bounded below by a constant δ > 0 such that δ > α / ( n + 2 ) . Then the first eigenvalue λ 1 ( p ) of the Hodge Laplacian Δ ( p ) satisfies the inequality λ 1 ( p ) ( 1 / 3 ) ( ( n + 2 ) δ α ) ( n p ) .
Remark 2.
In particular, if ( M , g ) is a Riemannian manifold with curvature operator of the second kind bounded below by a positive constant ρ > 0 , then using the main theorem from [14], we conclude that λ 1 ( p ) ρ ( n p ) .
Conformal Killing p-forms ( p = 1 , , n 1 ) were defined on Riemannian manifolds more than fifty years ago by S. Tachibana and T. Kashiwada (see [15,16]) as a natural generalization of conformal Killing vector fields.
The vector space of conformal Killing p-forms on a compact Riemannian manifold ( M , g ) has finite dimension t p ( M ) named the Tachibana number (see e.g., [17,18,19]). Tachibana numbers t 1 ( M ) , , t n 1 ( M ) are conformal scalar invariants of ( M , g ) satisfying the duality condition t p ( M ) = t n p ( M ) . The condition is an analog of the Poincaré duality for Betti numbers. Moreover, Tachibana numbers t 1 ( M ) , , t n 1 ( M ) are equal to zero on a compact Riemannian manifold with negative curvature operator or negative curvature operator of the second kind (see [18,19]).
We obtain the following theorem, which is an analog of Theorem 1.
Theorem 3.
Let ( M , g ) be an Einstein manifold with sectional curvature bounded above by a negative constant δ such that δ > α / ( n + 2 ) for the Einstein constant α. Then Tachibana numbers t 1 ( M ) , , t n 1 ( M ) are zero.

2. Proof of Results

Let ( M , g ) be an n-dimensional ( n 2 ) Riemannian manifold and let R i j k l and R i j be, respectively, the components of the Riemannian curvature tensor and the Ricci tensor in orthonormal basis { e 1 , , e n } of T x M at any point x M . We consider an arbitrary symmetric two-tensor φ on ( M , g ) . At any point x M , we can diagonalize φ with respect to g, using orthonormal basis { e 1 , , e n } of T x M . In this case, the components of φ have the form φ i j = λ i δ i j . Let sec ( e i , e j ) be the sectional curvature of the plane of T x M generated by e i and e j . We can express sec ( e i , e j ) in the following form (see [1] (p. 436); [20]):
1 2 i j sec ( e i , e j ) ( λ i λ j ) 2 = R i j l k φ i k φ j l + R i j φ i k φ k j
If ( M , g ) is an Einstein manifold and its sectional curvature satisfies the inequality sec δ for a positive constant δ , then from Equation (1) we obtain the inequality
R i j l k φ i k φ j l + s n φ i k φ i k ( δ / 2 ) i j ( λ i λ j ) 2 .
If trace g φ = i λ i = 0 , then the identity holds i ( λ i ) 2 = 2 i < j λ i λ j . In this case, the following identities are true:
1 2 i j ( λ i λ j ) 2 = ( n 1 ) i ( λ i ) 2 2 i < j λ i λ j = n i λ i 2 = n φ 2 .
Then the inequality in Equation (2) can be rewritten in the form
R i j l k φ i k φ j l + s n φ i k φ i k n δ φ 2 .
From Equation (3) we obtain the inequality
R i j l k φ i k φ j l ( n δ α ) φ 2 .
Then R > 0 for the case when α < n δ , where α = s / n is the Einstein constant of ( M , g ) . If ( M , g ) is compact then it is a spherical space form (see [9]). Theorem 1 is proven.
Define the quadratic form
F p ( ω ) = R i j ω i i 2 i p ω i 2 i p j p 1 2 R i j k l ω i j i 3 i p ω i 2 i p k l
for the components ω i 1 i p = ω ( e i 1 , , e i p ) of an arbitrary differential p-form ω . If the quadratic form F p ( ω ) is positive definite on a compact Riemannian manifold ( M , g ) , then the p-th Betti number of the manifold vanishes (see [21] (p. 61); [3] (p. 88)). At the same time, in [22] the following inequality
F p ( ω ) p ( n p ) ε ω 2 > 0
was proved for any nonzero p-form ω on a Riemannian manifold with R ¯ ε > 0 . On the other hand, in [14] the inequality
F p ( ω ) p ( n p ) δ ω 2 > 0
was proved for any nonzero p-form ω on a Riemannian manifold with R δ > 0 . In these cases, b 1 ( M ) , , b n 1 ( M ) are zero (see [21]). We can improve these results for the case of Einstein manifolds. First, we will prove the following.
Lemma 1.
Let ( M , g ) be an Einstein manifold with Einstein constant α and sectional curvature bounded below by a constant δ > 0 . If α < ( n + 2 ) δ then
F p ( ω ) ( 1 / 3 ) ( ( n + 2 ) δ α ) ( n p ) ω 2 > 0
for any nonzero p-form ω and an arbitrary 1 p n 1 .
Proof. 
Let p [ n / 2 ] , then we can define the symmetric traceless two-tensor φ i 1 i 2 i p with components (see [14])
φ j k i 1 i 2 i p = a = 1 p ω i 1 i a 1 j i a + 1 i p g k i a + ω i 1 i a 1 k i a + 1 i p g j i a 2 p n g j k ω i 1 i p
for each set of values of indices i 1 i 2 i p such that 1 i 1 < i 2 < < i p n . After long but simple calculations we obtain the identities (see also [14]),
R i j k l φ i l i 1 i p φ i 1 i p j k = p ( 2 ( n + 4 p ) n R i j ω i i 2 i p ω i 2 i p j
3 p 1 R i j k l ω i j i 3 i p ω i 3 i p k l 4 p n 2 s ω 2 ) ;
φ ¯ 2 = 2 p ( n + 2 ) ( n p ) n ω 2 ,
where
φ ¯ 2 = g i k g j l g i 1 j 1 g i p j p φ i j i 1 i p φ k l j 1 j p , ω 2 = ω i 1 i 2 i p ω i 1 i 2 i p = g i 1 j 1 g i p j p ω i 1 i p ω j 1 j p
for g i j = ( g 1 ) i j . If ( M , g ) is an Einstein manifold, then Equations (4) and (5) can be rewritten in the form
F p ( ω ) = s n ω 2 p 1 2 R i j k l ω i j i 3 i p ω i 3 i p k l ,
R i j k l φ i l ( i 1 i p ) φ i 1 i p j k = p 2 n + 4 p n 2 s ω 2 3 ( p 1 ) R i j k l ω i j i 3 i p ω i 3 i p k l .
On the other hand, for a fixed set of values of indices ( i 1 , i 2 , , i p ) such that 1 i 1 < i 2 < < i p n , the equality in Equation (3) can be rewritten in the form
R i j k l φ i l i 1 i p φ j k i 1 i p + s n φ i k i 1 i p φ i k i 1 i p n δ φ k l i 1 i p φ k l i 1 i p .
Then from Equation (8) we obtain the inequality
R i j k l φ i l i 1 i p φ i 1 i p j k n δ s n φ ¯ 2 .
Using Equation (9) we deduce from Equation (7) the following inequality:
6 p F p ( ω ) n δ s n + 2 φ ¯ 2 .
Thus, using Equation (6) we can rewrite Equation (10) in the following form:
F p ( ω ) ( 1 / 3 ) ( ( n + 2 ) δ α ) ( n p ) ω 2 .
It is obvious that if the sectional curvature of an Einstein manifold ( M , g ) satisfies the inequality sec δ for a positive constant δ , then the scalar curvature of ( M , g ) satisfies the inequality s n ( n 1 ) δ > 0 . In this case, if ( n 1 ) δ α < ( n + 2 ) δ , then from Equation (11) we deduce that the quadratic form F p ( ω ) is positive definite for any p [ n / 2 ] . It is known [23] that F p ( ω ) = F n p ( ω ) and ω 2 = ω 2 for any p-form ω with 1 p n 1 and the Hodge star operator : Λ p M Λ n p M acting on the space of p-forms Λ p M . Therefore, the inequality in Equation (11) holds for any p = 1 , , n 1 . □
Recall that if on an n-dimensional compact Riemannian manifold ( M , g ) the quadratic form F p ( ω ) is positive definite for any smooth p-form ω with p = 1 , , n 1 , then the Betti numbers b 1 ( M ) , , b n 1 ( M ) vanish (see [3] (p. 88); [13] (pp. 336–337)). In this case, Theorem 2 directly follows from Lemma 1.
If the curvature of an Einstein manifold ( M , g ) satisfies sec δ < 0 for a positive constant δ , then the Einstein constant of ( M , g ) satisfies the the obvious inequality α ( n 1 ) δ < 0 . On the other hand, from Equation (1) we deduce the inequality R i j l k φ i k φ j l n δ + α φ 2 . Therefore, if δ > α / n , then R < 0 . In this case, the Tachibana numbers t 1 ( M ) , , t n 1 ( M ) are equal to zero (see [19]). We proved the following.
Proposition 1.
Let ( M n , g ) be an Einstein manifold with sectional curvature bounded above by a negative constant δ such that δ > α / n for the Einstein constant α. Then the Tachibana numbers t 1 ( M ) , , t n 1 ( M ) are zero.
We can complete this result. If an Einstein manifold ( M n , g ) satisfies the curvature inequality sec δ < 0 for a positive constant δ , then from Equations (3) and (7) we deduce the inequality F p ( ω ) 1 3 ( ( n + 2 ) δ + α ) ( n p ) ω 2 for any p = 1 , , n 1 . Therefore, the Tachibana numbers t 1 ( M ) , , t n 1 ( M ) of a compact Einstein manifold with sectional curvature bounded above by a negative constant δ such that δ α / ( n + 2 ) are zero.

Author Contributions

Investigation, V.R., S.S. and I.T.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

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Rovenski, V.; Stepanov, S.; Tsyganok, I. On the Betti and Tachibana Numbers of Compact Einstein Manifolds. Mathematics 2019, 7, 1210. https://doi.org/10.3390/math7121210

AMA Style

Rovenski V, Stepanov S, Tsyganok I. On the Betti and Tachibana Numbers of Compact Einstein Manifolds. Mathematics. 2019; 7(12):1210. https://doi.org/10.3390/math7121210

Chicago/Turabian Style

Rovenski, Vladimir, Sergey Stepanov, and Irina Tsyganok. 2019. "On the Betti and Tachibana Numbers of Compact Einstein Manifolds" Mathematics 7, no. 12: 1210. https://doi.org/10.3390/math7121210

APA Style

Rovenski, V., Stepanov, S., & Tsyganok, I. (2019). On the Betti and Tachibana Numbers of Compact Einstein Manifolds. Mathematics, 7(12), 1210. https://doi.org/10.3390/math7121210

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