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Black hole information paradox and Bogoliubov quantum gravity kinetic equations

Black hole information paradox and Bogoliubov quantum gravity kinetic equations Igor V. Volovich Steklov Mathematical Institute , Moscow ROUND TABLE ITALY-RUSSIA@DUBNA Black Holes in Mathematics and Physics

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Black hole information paradox and Bogoliubov quantum gravity kinetic equations

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  1. Black hole information paradox and Bogoliubov quantum gravity kinetic equations Igor V. Volovich Steklov Mathematical Institute, Moscow ROUND TABLE ITALY-RUSSIA@DUBNA Black Holes in Mathematics and Physics Dubna, December 15 -- 18, 2011

  2. Black Hole Information Paradox • Time Irreversibility Problem (BH&BB) • Functional Formulation of Classical Mechanics and Field Theory • QG Boltzmann and Bogoliubov Equations

  3. Black hole entropy • Bekenstein-Hawking: Hawking radiation and Bogoliubov transformation

  4. Do Black Holes Really Exist? • Infinite time to form a black hole in Schwarzshild coordinates?

  5. Black hole information paradox • In 1976 Hawking has argued that the black hole creation and evaporation could lead to an evolution of a pure state into a mixed state. • This is in contradiction with the rules of quantum mechanics. • This has become known as the black hole information loss problem.

  6. Hawking first argument • If the material entering the black hole were a pure quantum state, the transformation of that state into the mixed state of Hawking radiation would destroy information about the original quantum state.

  7. `t Hooft, Susskind, Hawking… • Quantum gravity, baby universes, AdS/CFT,… • 1976: Information loss • 2005: No information loss • In 2005 Hawking has suggested that there is no information loss in black holes in asymptotically AdS (anti-de Sitter) spacetimes.

  8. Hawking second argument • The central point in his argument is the assertion that there is no information loss if one has a unitary evolution. • Then, since the AdS quantum gravity is dual to a unitary conformal field theory (AdS/CFT duality) there should be no information loss.

  9. Time Irreversibility problem • An important point in the argument is the assertion that, if one considers a theory with a unitary dynamics, there is no information loss problem. • We remind that the problem of how a unitary reversible dynamics can lead to an irreversible behavior (i.e. to information loss) is a famous fundamental problem in statistical physics.

  10. Time Irreversibility Problem • We consider the black hole information problem as a particular example of the fundamental irreversibility problem in statistical physics. Black hole vs. Black body.

  11. Time Irreversibility Problem Non-Newtonian Classical Mechanics Functional Probabilistic General Relativity • I. V. Found. Phys. (2011). • I.V. Theor. Math. Phys (2010)

  12. Time Irreversibility Problem The time irreversibility problem is the problem of how to explain the irreversible behaviour of macroscopic systems from the time-symmetric microscopiclaws: Newton, Schrodinger Eqs –- reversible Navier-Stokes, Boltzmann, diffusion, Entropy increasing --- irreversible

  13. Time Irreversibility Problem Boltzmann, Maxwell, Poincar´e, Bogolyubov, Kolmogorov, von Neumann, Landau, Prigogine, Feynman, Kozlov,… Poincar´e, Landau, Prigogine, Ginzburg, Feynman: Problem is open. We will never solve it (Poincare) Quantum measurement? (Landau) Lebowitz, Goldstein, Bricmont: Problem was solved by Boltzmann I.Volovich

  14. Boltzmann`s answers to: Loschmidt: statistical viewpoint Poincare—Zermelo: extremely long Poincare recurrence time Coarse graining • Not convincing…

  15. Ergodicity • Boltzmann, Poincare, Hopf, Kolmogorov, Anosov, Arnold, Sinai,…: • Ergodicity, mixing,… for various important deterministic mechanical and geometrical dynamical systems

  16. Bogolyubov method 1. Newton to Liouville Eq. Bogolyubov (BBGKI) hierarchy 2. Thermodynamic limit (infinite number of particles) 3. The condition of weakening of initial correlations between particles in the distant past 4. Functional conjecture 5. Expansion in powers of density Divergences.

  17. Why Newton`s mechanics can not be true? • Newton`s equations of motions use real numbers while one can observe only rationals. (s.i.) • Classical uncertainty relations • Time irreversibility problem • Singularities in general relativity

  18. Classical Uncertainty Relations

  19. Newton Equation Phase space (q,p), Hamilton dynamical flow

  20. Newton`s Classical Mechanics Motion of a point body is described by the trajectory inthe phase space. Solutions of the equations of Newton orHamilton. Idealization: Arbitrary real numbers—non observable. • Newton`s mechanics deals with non-observable (non-physical) quantities.

  21. Real Numbers • A real number is an infinite series, which is unphysical:

  22. Try to solve these problems by developing a new, non-Newtonian mechanics. • And new, non-Einsteinian general relativity

  23. We attempt the following solution of the irreversibility problem: a formulation of microscopic dynamics which is irreversible in time: Non-Newtonian Functional Approach.

  24. Functional formulation of classical mechanics • Here the physical meaning is attributed not to an individual trajectory but only to a bunch of trajectories or to the distribution function on the phase space. The fundamental equation of the microscopic dynamics in the proposed "functional" approach is not the Newton equation but the Liouville or Fokker-Planck-Kolmogorov (Langevin, Smoluchowski) equation for the distribution function of the single particle. • .

  25. States and Observables inFunctional Classical Mechanics

  26. States and Observables inFunctional Classical Mechanics Not a generalized function

  27. Fundamental Equation inFunctional Classical Mechanics Looks like the Liouville equation which is used in statistical physics todescribe a gas of particles but here we use it to describe a single particle.(moon,…) Instead of Newton equation. No trajectories!

  28. Cauchy Problem for Free Particle Poincare, Langevin, Smolukhowsky , Krylov, Bogoliubov, Blokhintsev, Born,…

  29. Free Motion

  30. Delocalization

  31. Newton`s Equation for Average

  32. Comparison with Quantum Mechanics

  33. Liouville and Newton. Characteristics

  34. Corrections to Newton`s EquationsNon-Newtonian Mechanics

  35. Corrections to Newton`s Equations

  36. Corrections to Newton`s Equations

  37. Corrections

  38. The Newton equation in this approach appears as an approximate equation describing the dynamics of the expected value of the position and momenta for not too large time intervals. • Corrections to the Newton equation are computed. • _____________________________ • _____________________________

  39. Fokker-Planck-Kolmogorov versus Newton

  40. Boltzmann and Bogolyubov Equations • A method for obtaining kinetic equations from the Newton equations of mechanics was proposed by Bogoliubov. This method has the following basic stages: • Liouville equation for the distribution function of particles in a finite volume, derive a chain of equations for the distribution functions, • pass to the infinite-volume, infinite number of particles limit, • postulate that the initial correlations between the particles were weaker in the remote past, • introduce the hypothesis that all many-particle distribution functions depend on time only via the one-particle distribution function, and use the formal expansion in power series in the density. • Non-Newtonian Functional Mechanics: • Finite volume. Two particles.

  41. Liouville equation for two particles

  42. Two particles in finite volume

  43. If satisfies the Liouville equation thenobeys to the following equation Bogolyubov type equation for two particles in finite volume

  44. Kinetic theory for two particles • Hydrodynamics for two particles?

  45. No classical determinism • Classical randomness • World is probabilistic (classical and quantum) Compare: Bohr, Heisenberg, von Neumann, Einstein,…

  46. Single particle (moon,…)

  47. Newton`s approach: Empty space (vacuum) and point particles. • Reductionism: For physics, biology economy, politics (freedom, liberty,…) • This approach: No empty space. Probability distribution. Collective phenomena.Subjective.

  48. Fixed classical spacetime? • A fixed classical background spacetime does not exists (Kaluza—Klein, Strings, Branes). No black hole metric. There is a set of classical universes and a probability distribution which satisfies the Liouville equation (not Wheeler—De Witt). Stochastic inflation?

  49. Functional General Relativity • Fixed background . Geodesics in functional mechanics Probability distributions of spacetimes • No fixed classical background spacetime. • No Penrose—Hawking singularity theorems • Stochastic geometry? Stochastic BH?

  50. Quantum gravity. Superstrings The sum over manifolds is not defined. Algorithmically unsolved problem.

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