All fundamental electrically charged thin shells in general relativity: From star shells to tension shell black holes and regular black holes and beyond

Lemos, José P. S.; Luz, Paulo

doi:10.48550/arxiv.2103.15832

Cited by 3 publications

(5 citation statements)

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“…At last, we should point our the thin wall model considered in the present work is uncharged. In general, the bubble wall produced in the charged spacetime background should be charged also [32,33]. For the future direction, it is interesting to consider the charged thin wall that separates the interior and the exterior spacetimes.…”

Section: Discussionmentioning

confidence: 99%

Vacuum decay and bubble nucleation in the anti-de Sitter black holes

Li,

Wang

2022

Preprint

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We study the vacuum decay and the bubble nucleation in the anti-de Sitter black holes. In the bubble nucleation spacetime, the interior and the exterior of the bubble wall are described by two anti-de Sitter black hole spacetimes with different cosmological constants. We calculate the Euclidean action of the bubble nucleation spacetime and give the numerical results of the tunneling rates for different cases. It is shown that the black hole can act as a source of inhomogeneities and catalyze the vacuum decay and the bubble nucleation in the anti-de Sitter spacetime. For the RNAdS black holes, the tunneling rate to the final RNAdS black hole with the minimum critical mass is the highest among all the possible tunneling channels.

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Section: Discussionmentioning

confidence: 99%

Vacuum decay and bubble nucleation in the anti-de Sitter black holes

Li,

Wang

2022

Preprint

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“…plus higher order terms of O (R − R 0 ) 3 . A thin matter shell with radius R 0 is stable or neutrally stable if and only if the potential V (R) satisfies V (R 0 ) = 0 and V (R 0 ) ≥ 0.…”

Section: Linearized Stability Analysis For Minkowski-minkowski Universesmentioning

confidence: 99%

“…In the same ambient Minkowski-Schwarzschild spacetime, if the normal points to decreasing coordinate radius r one has a tension shell black hole, i.e., a shell supported by tension that is in the other side of the Kruskal-Szekeres diagram as was noted by . This can also be performed in an ambient Minkowski-Reissner-Nordström spacetime, yielding, instead of two fundamental electrically charged shell spacetimes, a bewildering variety of fourteen fundamental electrically charged shell spacetimes with different global spacetime structures [3]. Here, in place of using an ambient Minkowski-Schwarzschild or an ambient Minkowski-Reissner-Nordström we use an ambient Minkowski-Minkowski spacetime.One possibility for a Minkowski-Minkowski spacetime is for a shell with a Minkowski interior with a center, i.e., a fundamental shell, such that the normal to the shell points towards decreasing radius r in the Minkowski exterior.…”

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confidence: 99%

Bubble universes and traversable wormholes

Lemos,

Luz

2022

Preprint

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I. INTRODUCTION A. Minkowski-Minkowski bubble universe and Minkowski-Minkowski traversable wormholeGeneral relativity is an excellent theory to study universe solutions and wormhole solutions from which bubble universes and traversable wormholes can arise as complementary to each other. To see this, one can attempt to find within the theory, Minkowski-Minkowski bubble universes and Minkowski-Minkowski traversable wormholes and study their properties. One picks up a Minkowski spacetime and at constant time cuts a ball in it, to obtain two spaces, namely, a 3-dimensional ball with a flat inside, and an infinite extended 3-dimensional flat space with a hole, which is the complement of the ball. Then one picks up another Minkowski spacetime and do the same, to get a second ball and a second infinite extended flat space with a hole. If one joins the two 3-dimensional balls along a 2-sphere, a shell containing matter, one obtains a single 3-space that including time makes altogether a static closed universe. If one joins the two complements, i.e., the two infinite extended 3-dimensional flat spaces with a hole in each, along a 2-sphere, a shell containing matter, one obtains a different single 3-space that including time makes altogether another universe, which is a traversable wormhole. Thus, one has a closed universe, which can be viewed as a bubble universe, and its complement, an open universe, which is a traversable wormhole. To implement the idea of a Minkowski-Minkowski closed universe, i.e., a bubble universe, and a Minkowski-Minkowski open universe, i.e., a traversable wormhole, one uses the equations of general relativity together with the appropriate thin shell formalism [1]. When one has a thin shell in an ambient spacetime one has the normal vector to the shell as an important quantity that will allow to determine how the thin shell curves in that space, i.e., allows to determine the extrinsic curvature of the shell, which besides the spacetime metric itself, is one of the quantities that has to match at both sides of the shell. Indeed, to find all possible shell solutions in an ambient spacetime one has to understand the fact that the normal to a shell can have two relative directions, such that, for static spherically symmetric spacetimes, the normal to the shell may point towards or away from the center of the coordinates. For intance, in an ambient Minkowski-Schwarzschild spacetime, more precisely, for a shell with a Minkowski interior with a center and a Schwarzschild exterior, usually called a fundamental shell, if the normal points to increasing coordinate radius r in the exterior, one has a star shell, i.e., a shell that represents a star. In the same ambient Minkowski-Schwarzschild spacetime, if the normal points to decreasing coordinate radius r one has a tension shell black hole, i.e., a shell supported by tension that is in the other side of the Kruskal-Szekeres diagram as was noted by . This can also be performed in an ambient Minkowski-Reissner-Nordström spacetime, yielding, instead of two fu...

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“…plus higher order terms of O (R − R 0 ) 3 . A thin matter shell with radius R 0 is stable or neutrally stable if and only…”

Section: Linearized Stability Analysis For Minkowski-minkowski Universesmentioning

confidence: 99%

“…In the same ambient Minkowski-Schwarzschild spacetime, if the normal points to decreasing coordinate radius r one has a tension shell black hole, i.e., a shell supported by tension that is in the other side of the Kruskal-Szekeres diagram as was noted by Katz and Lynden-Bell [2]. This can also be performed in an ambient Minkowski-Reissner-Nordström spacetime, yielding, instead of two fundamental electrically charged shell spacetimes, a bewildering variety of fourteen fundamental electrically charged shell spacetimes with different global spacetime structures [3]. Here, in place of using an ambient Minkowski-Schwarzschild or an ambient Minkowski-Reissner-Nordström we use an ambient Minkowski-Minkowski spacetime.…”

Section: Introduction a Minkowski-minkowski Bubble Universe And Minko...mentioning

confidence: 95%