On General Plane Fronted Waves. Geodesics

Candela, Anna Maria; Flores, José Luis; Sánchez, Miguel Azpitarte

doi:10.1023/a:1022962017685

Cited by 68 publications

(143 citation statements)

References 31 publications

Supporting

Mentioning

141

Contrasting

Order By: Relevance

“…A particular class is the class of polarized exact plane waves with a potential H(u, x, y) = h(u)(x 2 − y 2 ) [7]. Isometric, homothetic and conformal vector fields of pp-waves were classified in a kind of a recursive normal form in [39], starting from the possible Killing fields.…”

Section: Theorem 22 (Alternative Version)mentioning

confidence: 99%

Einstein Spaces with a Conformal Group

Kühnel

Rademacher

2009

Results. Math.

View full text Add to dashboard Cite

Abstract. The pseudo-Riemannian Einstein spaces with a (local or global) conformal group of strictly positive dimension can be classified. In this article we give a straightforward and systematic proof. As a common generalization, this includes the global theorem of Yano and Nagano in the Riemannian case (1959, published in the Annals of Mathematics) and a pseudo-Riemannian analogue proved by Kerckhove in his 1988 thesis under Professor K.Nomizu. We extend and unify the previous results in the case of an indefinite metric by analogy with the case of a positive definite metric.

show abstract

Section: Theorem 22 (Alternative Version)mentioning

confidence: 99%

Einstein Spaces with a Conformal Group

Kühnel

Rademacher

2009

Results. Math.

View full text Add to dashboard Cite

show abstract

“…In this ambient, a name as generalized ppwave or "M -fronted wave with parallel rays" (M p-wave) seems natural for our spacetimes (1.1). Nevertheless, we will maintain the name PFW (plane fronted wave) in agreement with previous references [17,26] or the nomenclature in [4], but with no further pretension.…”

Section: Definitionsmentioning

confidence: 78%

“…The authors, in collaboration with A.M. Candela [17], considered the following class of spacetimes, say PFW, which essentially include classical pp-waves (and, thus, plane waves):…”

Section: Introductionmentioning

confidence: 99%

“…In this framework, our goals in [17,26] were, essentially: (i) to introduce the class of reasonably generic waves (1.1), (ii) to justify that, for a physically reasonable asymptotic behaviour of the wave, |H(·, u)| must be "subquadratic" (plane waves lie in the limit quadratic case), and (iii) to show that, in this case, the geometry of the wave presents good global properties: global hyperbolicity [26] and geodesic connectedness [17]. Even more, the unstability of these geometric properties in the quadratic case implied interesting questions in Riemannian Geometry, studied in [15].…”

Section: Introductionmentioning

confidence: 99%

“…In the present article, we explain the role of the mathematical tools introduced in [17,15,26] in relation to both, classical problems on waves as [39,21], and posterior developments [34,31,33,32,35,45]. The proofs are referred to the original articles, or sketched in the case of further results.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

On the Geometry of pp-Wave Type Spacetimes

Flores

Sánchez

Analytical and Numerical Approaches to Mathematical Relativity

View full text Add to dashboard Cite

Abstract.Global geometric properties of product manifolds M = M × R 2 , endowed with a metric type ·, · = ·, · R + 2dudv + H(x, u)du 2 (where ·, · R is a Riemannian metric on M and H : M × R → R a function), which generalize classical plane waves, are revisited. Our study covers causality (causal ladder, inexistence of horizons), geodesic completeness, geodesic connectedness and existence of conjugate points. Appropiate mathematical tools for each problem are emphasized and the necessity to improve several Riemannian (positive definite) results is claimed.The behaviour of H(x, u) for large spatial component x becomes essential, being a spatial quadratic behaviour critical for many geometrical properties. In particular, when M is complete, if −H(x, u) is spatially subquadratic, the spacetime becomes globally hyperbolic and geodesically connected. But if a quadratic behaviour is allowed (as happen in plane waves) then both global hyperbolicity and geodesic connectedness maybe lost.From the viewpoint of classical General Relativity, the properties which remain true under generic hypotheses on M (as subquadraticity for H) become meaningful. Natural assumptions on the wave -finiteness or asymptotic flatness of the front-imply the spatial subquadratic behaviour of |H(x, u)| and, thus, strong results for the geometry of the wave. These results not always hold for plane waves, which appear as an idealized non-generic limit case.

show abstract