Papers
Topics
Authors
Recent
Search
2000 character limit reached

Mass Superinflation from Enhanced Cauchy Horizon Singularity in a Reissner-Nordström Black Hole

Published 20 Jan 2024 in gr-qc | (2401.11220v1)

Abstract: Ever since Penrose and Simpson contradicted Novikov's prediction that an infalling passenger would emerge into an asymptotically flat universe, there have been a continued interest in predicting the nature of singularity at the Cauchy horizon of a Reissner-Nordstrom blackhole. This prediction was first confirmed by Poisson and Israel using cross-stream of massless particles, suggesting the phenomenon of mass inflation. Ori however obtained a weaker singularity using a null shell of radiation. In this work, we consider a massive scalar field coupled to the Reissner-Nordstrom geometry and analyze the nature of singularity at the Cauchy horizon. To study the asymptotic behavior of the mass function and the scalar field near the Cauchy horizon, we perturbatively solve the coupled dynamical equations emplyoing the Adomian decomposition method. Our analysis shows that the mass function exhibits a very rapid and unbounded double-exponential growth, called herein mass superinflation, which is enormously stronger than previously obtained singularities. The scalar field is also found to undergo a very strong blueshift near the Cauchy horizon.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (38)
  1. Hans Reissner. Über die eigengravitation des elektrischen feldes nach der einsteinschen theorie. Annalen der Physik, 355(9):106–120, 1916.
  2. G Nordstrom. On the energy of the gravitational field in einstein’s theory ii verhandl. Koninkl. Ned. Akad. Wetenschap., Afdel. Natuurk., Amsterdam, 26:1201–1208, 1918.
  3. Roger Penrose. Gravitational collapse: The role of general relativity. Nuovo Cimento Rivista Serie, 1:252, 1969.
  4. ID Novikov. Change of relativistic collapse into anticollapse and kinematics of a charged sphere. JETP Lett.(USSR)(Engl. Transl.), 3, 1966.
  5. Internal instability in a reissner-nordström black hole. International Journal of Theoretical Physics, 7:183–197, 1973.
  6. R. Penrose. Battelle rencontres ‐ 1967 lectures in mathematics and physics (ed. by c. m. dewitt and j. a. wheeler). xvii + 557 s. m. fig. new york/amsterdam 1968. w. a. benjamin, inc. Zamm-zeitschrift Fur Angewandte Mathematik Und Mechanik, 50:782–782, 1970.
  7. Amos Ori. Inner structure of a charged black hole: An exact mass-inflation solution. Physical review letters, 67(7):789, 1991.
  8. The physics of the relativistic counter-streaming instability that drives mass inflation inside black holes. Physics reports, 495(1):1–32, 2010.
  9. Inner-horizon instability and mass inflation in black holes. Physical review letters, 63(16):1663, 1989.
  10. Internal structure of black holes. Physical Review D, 41(6):1796, 1990.
  11. Mass inflation in the loop black hole. Physical Review D, 84(10):104041, 2011.
  12. Richard H Price. Nonspherical perturbations of relativistic gravitational collapse. i. scalar and gravitational perturbations. Physical Review D, 5(10):2419, 1972.
  13. Frank J Tipler. Singularities in conformally flat spacetimes. Physics Letters A, 64(1):8–10, 1977.
  14. Singular space-times. General Relativity and Gravitation, 8:915–953, 1977.
  15. Analytic study of the null singularity inside spherical charged black holes. Physical Review D, 57(12):R7084, 1998.
  16. M Dafermos and J Luk. The interior of dynamical vacuum black holes i: the, 2017.
  17. Energy-momentum tensor near an evaporating black hole. Physical Review D, 13(10):2720, 1976.
  18. William A Hiscock. Stress-energy tensor near a charged, rotating, evaporating black hole. Physical Review D, 15(10):3054, 1977.
  19. Mass inflation: The semiclassical regime. Physical review letters, 70(1):13, 1993.
  20. Nicholas David Birrell and Paul Charles William Davies. Quantum fields in curved space. Cambridge university press, 1984.
  21. Internal structure of charged black holes. Physical Review D, 84(6):064020, 2011.
  22. Black hole inner horizon evaporation in semiclassical gravity. Classical and Quantum Gravity, 38(12):125003, 2021.
  23. Classical mass inflation versus semiclassical inner horizon inflation. Physical Review D, 106(12):124006, 2022.
  24. Regular black holes without mass inflation instability. Journal of High Energy Physics, 2022(9):1–14, 2022.
  25. Stable rotating regular black holes. Physical Review D, 106(10):104060, 2022.
  26. Tyler McMaken. Semiclassical instability of inner-extremal regular black holes. Physical Review D, 107(12):125023, 2023.
  27. PR Brady and E Poisson. Cauchy horizon instability for reissner-nordstrom black holes in de sitter space. Classical and Quantum Gravity, 9(1):121, 1992.
  28. Stability of black holes in de sitter space. Physical Review D, 41(2):403, 1990.
  29. Cauchy horizon singularity without mass inflation. Physical Review D, 47(10):4239, 1993.
  30. Black holes in de sitter space and the stability conjecture of cauchy horizons. Physical Review D, 52(2):666, 1995.
  31. TM Helliwell and DA Konkowski. Testing a stability conjecture for cauchy horizons. Physical Review D, 47(10):4322, 1993.
  32. DA Konkowski and TM Helliwell. Instabilities of the cauchy horizon in kerr black holes. Physical Review D, 50(2):841, 1994.
  33. Classical stability and quantum instability of black-hole cauchy horizons. Physical review letters, 74(8):1280, 1995.
  34. G Adomian. A review of the decomposition method and some recent results for nonlinear equations. Mathematical and Computer Modelling, 13(7):17–43, 1990.
  35. George Adomian. A review of the decomposition method in applied mathematics. Journal of mathematical analysis and applications, 135(2):501–544, 1988.
  36. George Adomian. Solving frontier problems of physics: the decomposition method, volume 60. Springer Science & Business Media, 2013.
  37. George Adomian. Nonlinear stochastic operator equations. Academic press, 2014.
  38. A review of the adomian decomposition method and its applications to fractional differential equations. Communications in Fractional Calculus, 3(2):73–99, 2012.

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 1 tweet with 0 likes about this paper.

Sign Up for Free