Traversable wormholes in light of class I approach

Francisco Tello-Ortiz; E. Contreras

doi:10.1016/j.aop.2020.168217

Traversable wormholes in light of class I approach

Francisco Tello-Ortiz^*
, E. Contreras

^*Corresponding author for this work

Física

Universidad de Antofagasta

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

In this work, we employ the class I approach to obtain wormhole solutions in the framework of general relativity in two different ways. Firstly, we propose a suitable red-shift function in order to find its associated shape function. Afterwards, we solve the inverse problem, namely, we impose the well known Morris–Thorne shape function to obtain the corresponding red-shift. It is found that, on one hand, the first model satisfies all the general requirements of a traversable wormhole. On the other hand, although the second solution violates the null energy condition at the throat as expected, the solution is not asymptotically flat. The study is complemented by analyzing the hydrostatic balance of the system by means of the modified relativistic hydrostatic equilibrium equation.

Original language	English
Article number	168217
Journal	Annals of Physics
Volume	419
DOIs	https://doi.org/10.1016/j.aop.2020.168217
State	Published - Aug 2020

Keywords

Embedding class I
Energy condition
Exotic matter distribution
Wormhole solution

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title = "Traversable wormholes in light of class I approach",

abstract = "In this work, we employ the class I approach to obtain wormhole solutions in the framework of general relativity in two different ways. Firstly, we propose a suitable red-shift function in order to find its associated shape function. Afterwards, we solve the inverse problem, namely, we impose the well known Morris–Thorne shape function to obtain the corresponding red-shift. It is found that, on one hand, the first model satisfies all the general requirements of a traversable wormhole. On the other hand, although the second solution violates the null energy condition at the throat as expected, the solution is not asymptotically flat. The study is complemented by analyzing the hydrostatic balance of the system by means of the modified relativistic hydrostatic equilibrium equation.",

keywords = "Embedding class I, Energy condition, Exotic matter distribution, Wormhole solution",

author = "Francisco Tello-Ortiz and E. Contreras",

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T1 - Traversable wormholes in light of class I approach

AU - Tello-Ortiz, Francisco

AU - Contreras, E.

PY - 2020/8

Y1 - 2020/8

N2 - In this work, we employ the class I approach to obtain wormhole solutions in the framework of general relativity in two different ways. Firstly, we propose a suitable red-shift function in order to find its associated shape function. Afterwards, we solve the inverse problem, namely, we impose the well known Morris–Thorne shape function to obtain the corresponding red-shift. It is found that, on one hand, the first model satisfies all the general requirements of a traversable wormhole. On the other hand, although the second solution violates the null energy condition at the throat as expected, the solution is not asymptotically flat. The study is complemented by analyzing the hydrostatic balance of the system by means of the modified relativistic hydrostatic equilibrium equation.

AB - In this work, we employ the class I approach to obtain wormhole solutions in the framework of general relativity in two different ways. Firstly, we propose a suitable red-shift function in order to find its associated shape function. Afterwards, we solve the inverse problem, namely, we impose the well known Morris–Thorne shape function to obtain the corresponding red-shift. It is found that, on one hand, the first model satisfies all the general requirements of a traversable wormhole. On the other hand, although the second solution violates the null energy condition at the throat as expected, the solution is not asymptotically flat. The study is complemented by analyzing the hydrostatic balance of the system by means of the modified relativistic hydrostatic equilibrium equation.

KW - Embedding class I

KW - Energy condition

KW - Exotic matter distribution

KW - Wormhole solution

UR - https://www.scopus.com/pages/publications/85085607728

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DO - 10.1016/j.aop.2020.168217

M3 - Artículo

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SN - 0003-4916

VL - 419

JO - Annals of Physics

JF - Annals of Physics

M1 - 168217

ER -

Traversable wormholes in light of class I approach

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Keywords

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