Kaluza–Klein equations, Einstein’s equations, and an effective energy-momentum tensor

Wesson, Paul S.; León, J. Ponce de

doi:10.1063/1.529834

Cited by 223 publications

(295 citation statements)

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“…Interior solutions for higher dimensional perfect-fluid have been discussed by Krori et al [4] and Shen et al [5]. Other interior solutions, as well as their physical properties, have been discussed in the context of "matter-from-geometry" theory, in which four-dimensional matter is interpreted as a manifestation of five-dimensional geometry [6,7].…”

Section: Introductionmentioning

confidence: 99%

Hydrostatic Equilibrium of a Perfect Fluid Sphere with Exterior Higher-Dimensional Schwarzschild Spacetime

León

Cruz

2000

General Relativity and Gravitation

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Abstract:We discuss the question of how the number of dimensions of space and time can influence the equilibrium configurations of stars. We find that dimensionality does increase the effect of mass but not the contribution of the pressure, which is the same in any dimension. In the presence of a (positive) cosmological constant the condition of hydrostatic equilibrium imposes a lower limit on mass and matter density. We show how this limit depends on the number of dimensions and suggest that Λ > 0 is more effective in 4D than in higher dimensions. We obtain a general limit for the degree of compactification (gravitational potential on the boundary) of perfect fluid stars in D-dimensions. We argue that the effects of gravity are stronger in 4D than in any other number of dimensions. The generality of the results is also discussed.

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Section: Introductionmentioning

confidence: 99%

Hydrostatic Equilibrium of a Perfect Fluid Sphere with Exterior Higher-Dimensional Schwarzschild Spacetime

León

Cruz

2000

General Relativity and Gravitation

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“…Concerning the field equations, the usual and simplest practice 2 is to take n = 4 and employ the 4 + 1 Einstein field equations. While this would provide a simple choice for the 4 + 1 field equations, it would cause the 3 + 1 apparent-world field equations to differ from the 3 + 1 GR Einstein field equations, as a result of projections of higher-d matter and 'matter' induced terms from the higher-d geometry [1,5].…”

Section: Foundations For Gr and Higher-d Gr Theoriesmentioning

confidence: 99%

“…We recall that the conventional formulation of GR has three main postulates. (i) 3 + 1 spacetime is a pseudo-Riemannian manifold, which is assumed to be the arena in which real physical events and interactions take place, (ii) Einstein field equations hold and (iii) light rays and freely-falling non-rotating, test-mass particles respectively follow the null and timelike geodesics of the spacetime 1 . This allows contact to be made with observations, and is intimately connected with the equivalence principle, according to which freely-falling non-rotating test particles follow timelike geodesics irrespective of their composition (see [13,14] for a thorough discussion).…”

Section: Foundations For Gr and Higher-d Gr Theoriesmentioning

confidence: 99%

“…Examples of such higher-d GR theories include (noncompactified) (n + 1)-d GR [1] (where the choice of the 3 + 1 apparent world is arbitrary), Kaluza-Klein theory [2] (where one dimension is compactified leading to a 3 + 1 apparent world described by GR, electromagnetism and a scalar), low energy string cosmology [3] (based on generalized compactifications), and some of the simpler braneworlds [4,5,6,7,8] (in which the apparent world consists of matter and tension restricted to a special brane hypersurface and the actual world is this hypersurface together with a surrounding bulk spacetime).…”

Section: Introductionmentioning

confidence: 99%

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Geodesics, the equivalence principle and singularities in higher-dimensional general relativity and braneworlds

Anderson

Tavakol

2005

J. Cosmol. Astropart. Phys.

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The geodesics of a spacetime seldom coincide with those of an embedded submanifold of codimension one. We investigate this issue for higher-dimensional general relativity-like models, firstly in the simpler case without branes to isolate which features are already present, and then in the more complicated case with branes. The framework in which we consider branes is general enough to include asymmetric braneworlds but not thick branes. We apply our results on geodesics to study both the equivalence principle and cosmological singularities. Among the models we study these considerations favour Z 2 symmetric braneworlds with a negative bulk cosmological constant.

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“…Such "braneworld" scenarios have been extensively analyzed in the literature, and have been used to address issues such as the hierarchy problem of particle physics [1,2,3,4], as well as the idea that the post-inflationary epoch of our universe was preceded by the collision of D3-branes [5,6]. In all fairness, it should be mentioned that the current flurry of interest in braneworld scenarios has been preceded by numerous other models making use of large or infinite extra dimensions [7,8,9,10,11,12].…”

Section: Introductionmentioning

confidence: 99%

Classical confinement of test particles in higher-dimensional models: Stability criteria and a new energy condition

Seahra

2003

Phys. Rev. D

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We review the circumstances under which test particles can be localized around a spacetime section Σ0 smoothly contained within a codimension-1 embedding space M . If such a confinement is possible, Σ0 is said to be totally geodesic. Using three different methods, we derive a stability condition for trapped test particles in terms of intrinsic geometrical quantities on Σ0 and M ; namely, confined paths are stable against perturbations if the gravitational stress-energy density on M is larger than that on Σ0, as measured by an observed travelling along the unperturbed trajectory. We confirm our general result explicitly in two different cases: the warped-product metric ansatz for (n + 1)-dimensional Einstein spaces, and a known solution of the 5-dimensional vacuum field equation embedding certain 4-dimensional cosmologies. We conclude by defining a confinement energy condition that can be used to classify geometries incorporating totally geodesic submanifolds, such as those found in thick braneworld and other 5-dimensional scenarios.

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Kaluza–Klein equations, Einstein’s equations, and an effective energy-momentum tensor

Cited by 223 publications

References 10 publications

Hydrostatic Equilibrium of a Perfect Fluid Sphere with Exterior Higher-Dimensional Schwarzschild Spacetime

Hydrostatic Equilibrium of a Perfect Fluid Sphere with Exterior Higher-Dimensional Schwarzschild Spacetime

Geodesics, the equivalence principle and singularities in higher-dimensional general relativity and braneworlds

Classical confinement of test particles in higher-dimensional models: Stability criteria and a new energy condition

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