Nikodem Janusz Popławski (born March 1, 1975) is a Polish theoretical physicist, most widely noted for the hypothesis that every black hole could be a doorway to another universe and that the universe was formed within a black hole which itself exists in a larger universe.[1] This hypothesis was listed by National Geographic and Science magazines among their top ten discoveries of 2010.[2][3]

Nikodem Popławski
Nikodem Popławski, 2015
Born (1975-03-01) 1 March 1975 (age 49)
Toruń, Poland
NationalityPolish, American
Alma mater
Known for
Scientific career
FieldsTheoretical physics
Institutions

Black holes as doorways

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Popławski's approach is based on the Einstein–Cartan theory of gravity which extends general relativity to matter with intrinsic angular momentum (spin). Spin in curved spacetime requires that the affine connection cannot be constrained to zero and its antisymmetric part, the torsion tensor, must be a variable in Hamilton's principle of stationary action which gives the field equations. Torsion gives the correct generalization of the conservation law for the total (orbital plus intrinsic) angular momentum to the presence of the gravitational field, but also modifies the Dirac equation for fermions.

Gravitational effects of torsion on fermionic matter are significant at extremely high densities which exist inside black holes and at the beginning of the Universe. Popławski theorizes that torsion manifests itself as a repulsive force which causes fermions to be spatially extended and prevents the formation of a gravitational singularity within the black hole's event horizon.[4] Because of torsion, the collapsing matter on the other side of the horizon reaches an enormous but finite density, explodes and rebounds, forming an Einstein-Rosen bridge (wormhole) to a new, closed, expanding universe.[5][6] Quantum particle production in strong gravitational fields helps torsion to overcome shear.[7][8][9] Analogously, the Big Bang is replaced by the Big Bounce before which the Universe was the interior of a black hole.[10] This scenario generates cosmic inflation, which explains why the present Universe at largest scales appears spatially flat, homogeneous and isotropic.[11][12] It may explain the arrow of time, solve the black hole information paradox, and explain the nature of dark matter.[13] Torsion may also be responsible for the observed asymmetry between matter and antimatter in the Universe.[14] The rotation of a black hole could influence the spacetime on the other side of its event horizon and result in a preferred direction in the new universe. Popławski suggests that the observed fluctuations in the cosmic microwave background might provide evidence for his hypothesis.[15]

Popławski proposed that the momentum components do not commute in the presence of torsion. Accordingly, integration over the continuous momentum in Feynman diagrams is replaced with summation over the discrete momentum eigenvalues whose separation increases with magnitude. Consequently, divergent integrals in Feynman diagrams are replaced with convergent sums. Therefore, torsion might eliminate ultraviolet divergence and provide a physical mechanism for regularization in quantum field theory, giving finite values of bare quantities such as the mass and electric charge of the electron.[16]

He also proposed that the four-velocity of a fermion (spinor) particle is related to its relativistic wave function. For a curved spacetime with torsion, the four-momentum of a spinor is related to a generator of translation, given by a covariant derivative, and the four-angular momentum is related to a generator of rotation in the Lorentz group. From the covariant conservation laws for the spin tensor and energy–momentum tensor for a spinor field in the presence of torsion, it follows that if the wave satisfies the curved Dirac equation, then the four-velocity, four-momentum, and four-spin satisfy the Mathisson–Papapetrou equations of motion, which reduce to the geodesic equation. Consequently, the motion of a particle guided by the four-velocity in the pilot wave interpretation of quantum mechanics coincides with the geodesic motion determined by spacetime, demonstrating a relativistic wave–particle duality.[17]

Education

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Popławski received his M.Sc. degree in astronomy from the University of Warsaw (1999), and his Ph.D. degree in physics from Indiana University (2004), where he later worked as a lecturer and researcher in theoretical physics. He joined the Department of Mathematics and Physics at the University of New Haven as a senior lecturer in 2013 and became a distinguished lecturer in 2020.

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Popławski appeared in an episode of the TV show Through the Wormhole titled "Are There Parallel Universes?" (season 2) and in an episode of the Discovery Channel show Curiosity titled "Is There a Parallel Universe?",[18] which aired in 2011.

See also

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References

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  1. ^ National Geographic Daily News: "Every Black Hole Contains Another Universe?"
    Science News: "Does Our Universe Live Inside a Wormhole?"
    Space.com: "Our Universe Was Born in a Black Hole, Theory Says"
    "Every black hole may hold a hidden universe" in New Scientist, Vol. 207, No. 2770, p. 9 (2010)
    National Geographic Daily News: "Are We Living in a Black Hole?"
    BBC iWonder: "How do we know the Big Bang actually happened?"
    Smithsonian: "What Is the Universe? Real Physics Has Some Mind-Bending Answers"
  2. ^ National Geographic Daily News: "Top Ten Discoveries of 2010: Nat Geo News's Most Popular"
  3. ^ Science News: "Top 10 ScienceNOWs of 2010"
  4. ^ N. J. Popławski (2010). "Nonsingular Dirac particles in spacetime with torsion". Physics Letters B. 690 (1): 73–77. arXiv:0910.1181. Bibcode:2010PhLB..690...73P. doi:10.1016/j.physletb.2010.04.073.
  5. ^ N. J. Popławski (2010). "Radial motion into an Einstein-Rosen bridge". Physics Letters B. 687 (2–3): 110–113. arXiv:0902.1994. Bibcode:2010PhLB..687..110P. doi:10.1016/j.physletb.2010.03.029. S2CID 5947253.
  6. ^ N. J. Popławski (2010). "Cosmology with torsion: An alternative to cosmic inflation". Physics Letters B. 694 (3): 181–185. arXiv:1007.0587. Bibcode:2010PhLB..694..181P. doi:10.1016/j.physletb.2010.09.056.
  7. ^ N. Popławski (2021). "Гравитационный коллапс жидкого объекта с кручением с образованием вселенной в черной дыре". Zhurnal Eksperimental'noi i Teoreticheskoi Fiziki. 159 (3): 448–456. arXiv:2008.02136. doi:10.31857/S0044451021030068. S2CID 234355453.
  8. ^ N. Popławski (2021). "Gravitational collapse of a fluid with torsion into a universe in a black hole". Journal of Experimental and Theoretical Physics. 132 (3): 374–380. arXiv:2008.02136. Bibcode:2021JETP..132..374N. doi:10.1134/S1063776121030092.
  9. ^ N. Popławski (2023). "Chapter 13: Gravitational Collapse with Torsion and Universe in a Black Hole". In C. Bambi (ed.). Regular Black Holes: Towards a New Paradigm of Gravitational Collapse. Springer. pp. 485–499. arXiv:2307.12190. doi:10.1007/978-981-99-1596-5_13.
  10. ^ N. Popławski (2012). "Nonsingular, big-bounce cosmology from spinor-torsion coupling". Physical Review D. 85 (10): 107502. arXiv:1111.4595. Bibcode:2012PhRvD..85j7502P. doi:10.1103/PhysRevD.85.107502. S2CID 118434253.
  11. ^ N. Popławski (2016). "Universe in a black hole in Einstein-Cartan gravity". Astrophysical Journal. 832 (2): 96. arXiv:1410.3881. Bibcode:2016ApJ...832...96P. doi:10.3847/0004-637X/832/2/96. S2CID 119771613.
  12. ^ G. Unger, N. Popławski (2019). "Big Bounce and closed Universe from spin and torsion". Astrophysical Journal. 870 (2): 78. arXiv:1808.08327. Bibcode:2019ApJ...870...78U. doi:10.3847/1538-4357/aaf169. S2CID 119514549.
  13. ^ N. J. Popławski (2014). "The energy and momentum of the Universe". Classical and Quantum Gravity. 31 (6): 065005. arXiv:1305.6977. Bibcode:2014CQGra..31f5005P. doi:10.1088/0264-9381/31/6/065005. S2CID 118593046.
  14. ^ N. J. Popławski (2011). "Matter-antimatter asymmetry and dark matter from torsion". Physical Review D. 83 (8): 084033. arXiv:1101.4012. Bibcode:2011PhRvD..83h4033P. doi:10.1103/PhysRevD.83.084033. S2CID 119223239.
  15. ^ S. Desai, N. J. Popławski (2016). "Non-parametric reconstruction of an inflaton potential from Einstein–Cartan–Sciama–Kibble gravity with particle production". Physics Letters B. 755: 183–189. arXiv:1510.08834. Bibcode:2016PhLB..755..183D. doi:10.1016/j.physletb.2016.02.014. S2CID 55366841.
  16. ^ N. Popławski (2020). "Noncommutative momentum and torsional regularization". Foundations of Physics. 50 (9): 900–923. arXiv:1712.09997. Bibcode:2020FoPh...50..900P. doi:10.1007/s10701-020-00357-1. S2CID 220511295.
  17. ^ F. R. Benard Guedes, N. J. Popławski (2024). "General-relativistic wave–particle duality with torsion". Classical and Quantum Gravity. 41 (6): 065011. arXiv:2211.03234. doi:10.1088/1361-6382/ad1fcb.
  18. ^ Nikodem Poplawski - IMDb"
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