Abstract
Tubular neighborhoods play an important role in differential topology. We have applied these constructions to geometry of almost Hermitian manifolds. At first, we consider deformations of tensor structures on a normal tubular neighborhood of a submanifold in a Riemannian manifold. Further, an almost hyper Hermitian structure has been constructed on the tangent bundle TM with help of the Riemannian connection of an almost Hermitian structure on a manifold M then, we consider an embedding of the almost Hermitian manifold M in the corresponding normal tubular neighborhood of the null section in the tangent bundle TM equipped with the deformed almost hyper Hermitian structure of the special form. As a result, we have obtained that any Riemannian manifold M of dimension n can be embedded as a totally geodesic submanifold in a Kaehlerian manifold of dimension 2n (Theorem 6) and in a hyper Kaehlerian manifold of dimension 4n (Theorem 7). Such embeddings are “good” from the point of view of Riemannian geometry. They allow solving problems of Riemannian geometry by methods of Kaehlerian geometry (see Section 5 as an example). We can find similar situation in mathematical analysis (real and complex).
Highlights
If we take the restriction of the function ε ( p) on U it is clear that there exists a continuous positive function ε ( p) such that for any p∈M′
The tensor field K is called a deformation of the tensor field K on the normal tubular neighborhood of a submanifold M ′
For an almost Hermitian manifold (M, J, g) we have constructed in Section 2 Almost Hyper Hermitian Structures (ahHs) ( J1, J2, J3, g ) on TM
Summary
For an almost Hermitian manifold (M, J, g) we have constructed in Section 2 ahHs ( J1, J2 , J3, g ) on TM. Let (M, J, g) be an almost Hermitian manifold and Tb (M ,ε ( p)) be the corresponding normal tubular neighborhood with respect to g = , on TM. It follows from Theorem 1 that M is a totally geodesic submanifold of the Riemannian manifold. Let W 0 be a coordinate neighborhood in TM considered in 1 ̊, Section 1. It follows that ∇Xi J = 0 for i= n +1, 2n. Let (M, g) be a smooth Riemannian manifold and Tb (M ,ε ( p)) be the corresponding normal tubular neighborhood with respect to g = , on TM. M(OM) is a totally geodesic submanifold of the Kaehlerian manifold.
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