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1996 | Buch

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Lightlike Submanifolds of Semi-Riemannian Manifolds and Applications

verfasst von: Krishan L. Duggal, Aurel Bejancu

Verlag: Springer Netherlands

Buchreihe : Mathematics and Its Applications

Enthalten in: Professional Book Archive

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Über dieses Buch

This book is about the light like (degenerate) geometry of submanifolds needed to fill a gap in the general theory of submanifolds. The growing importance of light like hypersurfaces in mathematical physics, in particular their extensive use in relativity, and very limited information available on the general theory of lightlike submanifolds, motivated the present authors, in 1990, to do collaborative research on the subject matter of this book. Based on a series of author's papers (Bejancu [3], Bejancu-Duggal [1,3], Dug gal [13], Duggal-Bejancu [1,2,3]) and several other researchers, this volume was conceived and developed during the Fall '91 and Fall '94 visits of Bejancu to the University of Windsor, Canada. The primary difference between the lightlike submanifold and that of its non degenerate counterpart arises due to the fact that in the first case, the normal vector bundle intersects with the tangent bundle of the submanifold. Thus, one fails to use, in the usual way, the theory of non-degenerate submanifolds (cf. Chen [1]) to define the induced geometric objects (such as linear connection, second fundamental form, Gauss and Weingarten equations) on the light like submanifold. Some work is known on null hypersurfaces and degenerate submanifolds (see an up-to-date list of references on pages 138 and 140 respectively). Our approach, in this book, has the following outstanding features: (a) It is the first-ever attempt of an up-to-date information on null curves, lightlike hypersur faces and submanifolds, consistent with the theory of non-degenerate submanifolds.

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Inhaltsverzeichnis

Frontmatter

Chapter 1. Algebraic Preliminaries

Abstract

This chapter reviews the algebraic preliminaries on semi-Euclidean spaces and their subspaces which we need in the development of the book. Most of the material should be familar to the reader, but we stress with a quasi-orthonormal basis induced by degenerate subspaces, which some readers may find unfamiliar. In particular, we included the null tetrad formalism, used in relativity, the linear isometries of semi-Euclidean spaces and their semi-orthogonal groups.

Krishan L. Duggal, Aurel Bejancu

Chapter 2. Differential-Geometric Structures On Manifolds

Abstract

In the present chapter we provide most of the prerequisites for reading the rest of the book. In the first two sections we present a review of vector bundles and introduce the main differential operators: Lie derivative, exterior differential, linear connection, general connection. Distributions on manifolds (known as non-holonomic spaces in classical terminology) are then introduced and studied by using both methods of vector fields and of differential 1-forms. We give here the characterization for the existence of a transversal distribution to a foliation, which is found to be very useful in Chapters 4 and 5 for a general study of lightlike submanifolds. In the last two sections we deal with semi-Riemannian manifolds and lightlike manifolds. While the geometry of a semi-Riemannian manifold is fully developed by using the Levi-Civita connection we stress the role of the radical distribution in studying the geometry of a lightlike manifold. The main formulas and results are expressed by using both the invariant form and the index form.

Krishan L. Duggal, Aurel Bejancu

Chapter 3. Geometry of Null Curves in Lorentz Manifolds

Abstract

The purpose of this chapter is to present the basic results on the general study of null curves in Lorentz manifolds. The reader will know at the end of this chapter as to why the discussion is restricted to Lorentz manifolds.

Krishan L. Duggal, Aurel Bejancu

Chapter 4. Lightlike Hypersurfaces of Semi-Riemannian Manifolds

Abstract

Here we develop a theory on the differential geometry of a lightlike hypersurface M of a proper semi-Riemannian manifold \(\bar M\) For this purpose, we introduce a non-degenerate screen distribution and construct the corresponding lightlike transversal vector bundle tr(TM) of M, consistent with the well-known theory of Riemannian submanifolds. This enables one to define the induced geometrical objects such as linear connection, second fundamental form, shape operator, etc., and to obtain the Gauss-Codazzi equations leading to the Fundamental Theorem of lightlike hyper-surfaces. It is noteworthy that the second fundamental form (and, therefore, the results on totally geodesic and totally umbilical lightlike hypersurfaces) is independent of the choice of a screen distribution.

Krishan L. Duggal, Aurel Bejancu

Chapter 5. Lightlike Submanifolds Of Semi-Riemannian Manifolds

Abstract

The primary difference between the theory of lightlike submanifolds and the classical theory of Riemannian or semi-Riemannian submanifolds arises due to the fact that in the first case, a part of the normal vector bundle TM ^⊥ lies in the tangent bundle TM of the submanifold M of \(\bar M\), where as in the second case TM ∩ TM ^⊥ = {0}. Thus, first basic problem of the lightlike submaniflds is to replace the intersecting part by a vector subbundle whose sections are no where tangent to M. Following the technique used in Chapter 4, we use a screen distribution S(TM) on M and a screen vector bundle S(TM ^⊥) over M, to construct a transversal vector bundle tr(TM) of M. The general theory is much more involved and rather difficult than the special case of lightlike hypersurfaces discussed in Chapter 4, in particular reference to the dependence of all the induced geometric objects on the triplet (S(TM), S(TM ^⊥), tr(TM)). We obtain the structure equations of M which relate the curvature tensor of \(\bar M\) with the curvature tensors of the linear connections induced on the vector bundles involved in the study. Finally, we present some results on differential geometry of lightlike surfaces of Lorentz manifolds, in particular attention to the case when \(\bar M = \mathbb{R}_1^4\).

Krishan L. Duggal, Aurel Bejancu

Chapter 6. CR Lightlike Submanifolds of Indefinite Kaehler Manifolds

Abstract

In this Chapter, we study Cauchy Riemann (CR) lightlike hypersurfaces and submanifolds (in general) of indefinite Hermitian and Kaehler manifolds. We prove that a lightlike real hypersurface M of an indefinite Hermitian manifold is a CR manifold and show that the integrability of all distributions of M is characterized by both second fundamental forms of M and its screen distribution S(TM). Finally, we study the geometry of various foliations on a CR lightlike submanifold and the existence of CR lightlike products of \(\bar M\).

Krishan L. Duggal, Aurel Bejancu

Chapter 7. Lightlike Hypersurfaces of Lorentz Framed Manifolds

Abstract

In the previous Chapter 6, we studied a class of lightlike submanifolds of Kaehler manifolds which are necessarily even dimensional. In this chapter, we consider a more general ambient manifold, called framed manifold of even as well as odd dimension. The reader will soon know why we concentrate on Lorentz manifolds. In section 7.1, we brief the needed information on the framed structure of a Lorentz manifold, which is then used, in section 7.2, to construct a class of invariant lightlike framed hypersurfaces. Section 7.3 is devoted to the study of a large class of lightlike framed hypersurfaces of globally hyperbolic spacetimes. In particular, we show that Minkowski and extended Schwarzchild spacetimes can be endowed with a framed structure and these spaces do have lightlike hypersurfaces with induced framed structure.

Krishan L. Duggal, Aurel Bejancu

Chapter 8. Lightlike Hypersurfaces And Electromagnetism

Abstract

In this Chapter we apply some results of Chapters 4 and 7 to study a class of lightlike hypersurfaces M of 4-dimensional electromagnetic spacetimes. Section 8.1 deals with the needed basic information on Minkowski spacetime. In section 8.2, we study a class of invariant lightlike hypersurfaces having induced non-singular and singular electromagnetic tensor fields denoted by F. We show that F on M exists if and only if M is totally geodesic. Section 8.3 deals with some geometric properties of (1,1) tensor fields (associated to F) satisfying an algebraic cubic equation. We show that a class of electromagnetic invariant lightlike hypersurfaces comes from the physically significant homogeneous spacetime manifolds of general relativity.

Krishan L. Duggal, Aurel Bejancu

Chapter 9. Lightlike Hypersurfaces and General Relativity

Abstract

Here we investigate some possible choices (Ricci flat, Einstein and pure radiation type) of the induced energy momentum tensor on a class of totally geodesic lightlike hypersurfaces M of 4-dimensional spacetime manifolds. We show that there does not exist any induced non-singular electromagnetic energy momentum tensor field and its singular type belongs to a class of pure radiation fields. Based on this, in sections 9.2 and 9.3, we study some properties of induced conformal and affine conformal vector fields, on M, respectively. Finally, we present a few examples of lightlike hypersurfaces of physically significant spacetimes of relativity.

Krishan L. Duggal, Aurel Bejancu

Backmatter

Titel: Lightlike Submanifolds of Semi-Riemannian Manifolds and Applications
verfasst von: Krishan L. Duggal
Aurel Bejancu
Copyright-Jahr: 1996
Verlag: Springer Netherlands
Electronic ISBN: 978-94-017-2089-2
Print ISBN: 978-90-481-4678-9
DOI: https://doi.org/10.1007/978-94-017-2089-2