Role of the irreducible mass in repetitive Penrose energy extraction processes in a Kerr black hole

Role of the irreducible mass in repetitive Penrose energy extraction processes in a Kerr black hole

The concept of the irreducible mass (M_{irr}) has led to the mass-energy (M) formula of a Kerr black hole (BH), in turn leading to its surface area S=16πM_{irr}^{2}. This also allowed the coeval identification of the reversible and irreversible transformations, soon followed by the concepts of extra...

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Bibliographic Details
Main Authors: R. Ruffini, C. L. Bianco, M. Prakapenia, H. Quevedo, J. A. Rueda, S. Zhang
Format: Article
Language:English
Published: American Physical Society 2025-02-01
Series:Physical Review Research
Online Access:http://doi.org/10.1103/PhysRevResearch.7.013203
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Summary:The concept of the irreducible mass (M_{irr}) has led to the mass-energy (M) formula of a Kerr black hole (BH), in turn leading to its surface area S=16πM_{irr}^{2}. This also allowed the coeval identification of the reversible and irreversible transformations, soon followed by the concepts of extracted and extractable energy. This new conceptual framework avoids inconsistencies recently evidenced in a repetitive Penrose process. We consider repetitive decays in the ergosphere of an initially extreme Kerr BH and show the processes are highly irreversible. For each decay, the particle that the BH captures causes an increase of the irreducible mass (so the BH horizon), much larger than the extracted energy. The energy extraction process stops when the BH reaches a positive spin lower limit set by the process boundary conditions. Thus, the reaching of a final nonrotating Schwarzschild BH state through this accretion process is impossible. We have assessed such processes for selected decay radii and incoming particle with rest mass 1% of the BH initial mass M_{0}. For r=1.2M and 1.9M, the sequence stops after 8 and 34 decays, respectively, at a spin 0.991 and 0.857, the energy extracted has been only 1.16%, and 0.42%, the extractable energy is reduced by 17% and 56%, and the irreducible mass increases by 5% and 22%, all values in units of M_{0}. These results show the highly nonlinear change of the BH parameters, dictated by the BH mass-energy formula, and that the BH rotational energy is mainly converted into irreducible mass. Thus, evaluating the irreducible mass increase in any energy extraction processes in the Kerr BH ergosphere is mandatory.
ISSN:2643-1564

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