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Stability of Charged Thin-Shell Wormholes with Weyl Corrections

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Abstract

This paper is devoted to examining the effects of charge and Weyl coupling parameter on the stable configuration of thin-shell wormholes. We use a cut and paste approach to develop thin-shell wormholes from the matching of two equivalent geometries of a charged black hole with Weyl corrections. The characteristics of matter surface around wormhole throat are calculated through Lanczos equations. We examine that matter distribution located at the wormhole throat violates the null and week energy conditions. The expansion and collapse of thin-shell are observed through the graphical behavior of surface pressure. We explore the stable behavior of wormhole throat through radial perturbation preserving its symmetries about the static solution. It is found that charge and Weyl coupling parameter enhances the stable regions of thin-shell wormholes but stable regions decrease for highly charged thin-shell wormholes.

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Funding

One of us (FJ) would like to thank the Higher Education Commission, Islamabad, for its financial support through 6748/Punjab/NRPU/RD/HEC/2016.

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Authors and Affiliations

  1. Department of Mathematics, University of the Punjab, Lahore, Pakistan

    M. Sharif & F. Javed

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  1. M. Sharif
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  2. F. Javed
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Correspondence to M. Sharif or F. Javed.

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Sharif, M., Javed, F. Stability of Charged Thin-Shell Wormholes with Weyl Corrections. Astron. Rep. 65, 353–361 (2021). https://doi.org/10.1134/S106377292105005X

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  • DOI: https://doi.org/10.1134/S106377292105005X

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