Gamma-ray (GRBs) and X-ray Bursts are millisecond-10 and 1000 seconds-long events of unknown origin. Recent simulations of the
merger of binary neutron star systems do not
generate a magnetically dominated called funnel nor a
relativistic outflow. New models for the detection the afterglow of GRB
121024A, measured 0.15 days after the burst,
invoke anisotropy as required to produce the complex microphysics of
realistic shocks in relativistic jets.
On the other hand the non-thermal gamma-rays are supposed to be produced
by a fireball of relativistic e−e+ pairs that are created
by annihilation of neutrino-antineutrino pairs in the vicinity of the hot,
merged object. It is also known that in a system of a large number of fermions
with pairs, gravitational interaction occurs a spontaneous breaking of the vacuum spatial symmetry, accompanied by
gravitational mass defect. If spherical symmetry is broken, as in the known
case of the merger scenario where a rapidly rotating disk can be formed and
material is pulled away from rotation axis by centrifugal forces, then a
baryon-free funnel along the rotation axes may allow relativistic beam ofγ’s and e−e+ to escape. It might lead to matter ejection with Lorentz
factors of ~102- 103 which are in the
right range to enable copious gamma production during shock interaction with ambient interstellar gas. Here we show that the space rays generation
mechanism on a method of direct transformation of intergalactic gamma-rays to
the proton current on spin shock-waves
References
[1]
Kawamura, T., Giacomazzo, B., Kastaun, W., Ciolfi, R., Endrizzi, A., Baiotti, L. and Perna, R. (2016) Binary Neutron Star Mergers and Short Gamma-Ray Bursts: Effects of Magnetic Field Orientation, Equation of State, and Mass Ratio. Physical Review D, 94, 064012. https://doi.org/10.1103/PhysRevD.94.064012
[2]
Wiersema, K., Covino, S., Toma, K., van der Horst, A.J., et al. (2014) Circular Polarization in the Optical Afterglow of GRB 121024A. Nature, 509, 201-204. https://doi.org/10.1038/nature13237
[3]
Piran, T. (2005) The Physics of Gamma-Ray Bursts. Reviews of Modern Physics, 76, 1143. https://doi.org/10.1103/RevModPhys.76.1143
[4]
Dado, S. and Dar, A. (2016) Critical Test of Gamma-Ray Burst Theories. Physical Review D, 94, 063007. https://doi.org/10.1103/PhysRevD.94.063007
[5]
Mitra, A. (2006) On the Non-Occurrence of Type I X-Ray Bursts from the Black Hole Candidates. Advances in Space Research, 38, 2917-2919. https://doi.org/10.1016/j.asr.2006.02.074
[6]
Tewari, B.C. and Charan, K. (2015) Horizon Free Eternally Collapsing Anisotropic Radiating Star. Astrophysics and Space Science, 357, 107. https://doi.org/10.1007/s10509-015-2335-2
[7]
Tewari, B.C., Charan, K. and Rami, J. (2016) Spherical Gravitational Collapse of Anisotropic Radiating Fluid Sphere. IJAA, 6, 155-165. https://doi.org/10.4236/ijaa.2016.62013
[8]
Berezinsky, V., Hnatyk, B. and Vilenkin, A. (2001) Gamma Ray Bursts from Superconducting Cosmic Strings. Physical Review D, 64, 043004. https://doi.org/10.1103/PhysRevD.64.043004
[9]
Janka, H.-T. and Ruffert, M. (1995) Can Neutrinos from Neutron Star Mergers Power Gamma-Ray Bursts? Astronomy and Astrophysics, 307 No. 2.
[10]
Syromyatnikov, A.G. (1991) Gauge Invariance Problem in Field Theory with Dynamic Torsion. Theoretical and Mathematical Physics, 87, 444-446. https://doi.org/10.1007/BF01016586
[11]
Satarov, A.G. and Syromyatnikov, A.G. (1992) O nekotorih osobennostyah dvuh podhodov k affinno-metricheskoi teorii gravitatcii [On Some Features of Two Approaches to the Affine-Metric Theory of Gravitation]. Theoretical and Mathematical Physics, 92, 1, 150.
[12]
Satarov, A.G. and Syromyatnikov, A.G. (1993) On Some Features of Two Approaches to the Affine-Metric Theory of Gravitation. Plenum Publishing Corporation, New York, 799-801.
[13]
Norden, A.P. (1976) Spaces of the Affine Connectivity. Nauka, Moscow.
[14]
Syromyatnikov, A.G. (2015) New Horizons in Nuclear Physics, Nuclear Engineering, Femto-and Nanotechnologies. Proceeding of the LXV International Conference “Nucleus-2015”, Saint-Petersburg, Russia, 29 June-3 July 2015, 173.
[15]
Syromyatnikov, A.G. (2015) Similarity All-Known Particle/Resonance Mass and Nuclear Atomic Weight. LAP Lambert Academic Publishing GmbH & Co. KG, Saarbrucken, Germany.
[16]
Syromyatnikov, A.G. (2012) A Possible Mechanism for the Generation of Cosmic Rays. Vestnik of Saint-Petersburg University, 4, 108-112.
[17]
Syromyatnikov, A.G. (1993) Method of Self-Consistent Field in Non-Linear Dynamics Problems. Tip. VKA, St. Petersburg, Russia.
[18]
Costa, E. and Frontera, F. (2011) Gamma Ray Burst Origin and Their Afterglow: Story of a Discovery and More. La Rivista del Nuovo Cimento, 34, 585-615. Arxiv:1107.1661
[19]
Teilor, J.H., Manchester, R.N. and Lyne, A.G. (1993) Catalog of 558 Pulsars. The Astrophysical Journal Supplement Series, 88, 529-568.
[20]
CBAT: IAU Central Bureau for Astronomical Telegrams (2005). http://www.cbat.eps.harvard.edu/lists/Supernovae.html
[21]
Syromyatnikov, A.G. (2015) On Some Features of Possible Torsion Effects on Observables at Hadron Colliders. International Journal of Geometric Methods in Modern Physics, 12, 1550080.
[22]
Syromyatnikov, A.G. (2016) The g-2 Muon Anomaly in Dimuon Production with the Torsion in LHC. International Journal of Geometric Methods in Modern Physics, 13, 1650093.
[23]
Syromyatnikov, A.G. (2012) Physical Effects of the Conformal Gauge Theory of Gravitation. LAP Lambert Academic Publishing GmbH & Co. KG, Saarbrucken, Germany.
[24]
Spitler, L.G., Scholz, P., Hessels, J.W.T., et al. (2016) A Repeating Fast Radio Burst. Nature 531, 202-205. https://doi.org/10.1038/nature17168
[25]
Popov, S.B. and Pshirkov, M.S. (2016) Fast Radio Bursts Counterparts in Scenario of Supergiant Pulses. Arxiv:1605.01992[astro-ph.HE]
