28 ноября 2023 г. to 1 декабря 2023 г.
Europe/Moscow timezone

Mutual dependence of a bosonic black hole with dark matter and explanation of asymptotically flat galaxy rotation curves.

28 нояб. 2023 г., 12:00
35m
Gravitation & Cosmology Morning session 28/11/2023

Speaker

Dr Boris Meierovich (Kapitza Insitute for Physical Problems RAS, Moscow)

Описание

Dark matter makes itself felt only due to the gravitational interaction. Quanta of ordinary matter in flat space are described by vector fields. Let us assume that the wave function of dark matter quanta is also a vector field. Then it makes sense to find such a vector field in the general theory of relativity, which manifests itself exclusively in curved space-time...(see other details in the articles below)

Information on the subject:
1.
Vector fields in multidimensional cosmology. Phys. Rev. D84, 064037 (2011) arXiv:1105.4420
2.
Vector fields in multidimensional cosmology. Proceedings of PIRT-2011 Moscow, p.211, (2012)
3.
Towards the theory of evolution of the Universe. Phys. Rev. D85, 123544 (2012) arXiv:1201.2562
4.
Galaxy rotation curves driven by massive vector fields: Key to the theory of dark sector. Phys. Rev. D87, 103510 (2013) arXiv:1303.7062
5.
Macroscopic theory of dark sector. Physical Interpretation of Relativity Theory Proceedings of International Scientific Meeting PIRT-2013. Moscow: 1-4 July, 2013. p440. Bauman Moscow State Technical University (2013)
6. Macroscopic theory of dark sector. Journ. of Gravity 2014, 586958 (2014)
7.
Phenomenological description of dark energy and dark matter by vector fields. Physical Interpretation of Relativity Theory. Proceedings of International Scientific Meeting PIRT-2015. Moscow: 29 June - 02 July, 2015. p 384. Bauman Moscow State Technical University (2015)
8.
Description of dark energy and dark matter by vector fields. Proceedings of the Tenth Asia-Pacific International Conference on Gravitation, Astrophysics, and Cosmology. Dedicated to the Centenary of Einstein's General Relativity. p 135 (2016) World Scientific Publishing Co.
9.
Motion in a Central Field with Account of Dark Matter. Gravitation and Cosmology 23(3), 251 (2017)
10. О равновесном состоянии гравитирующего конденсата Бозе-Эйнштейна ЖЭТФ 154(5), 1000 (2018)
11. Static State of a Black Hole Supported by Dark Matter. Universe 5(9), 198 (2019)
12. Black hole in balance with dark matter. International Journal of Modern Physics A35, (2&3), 2040050 (2020)
13. Black Hole and Dark Matter. Phase Equilibrium. J. Phys. CS 1557, 012030 (2020)
14. Guessing the Riddle of a Black Hole. Universe 6(8), 113 (2020)
15. Gravitational Radius in view of Existence and Uniqueness Theorem. J. Phys. CS 2081, 012026 (2021)
16. Bose-Einstein Condensate in Synchronous Coordinates. Phys. Sci. Forum 7, 47 (2023)
17. Черная дыра и темная материя в синхронной системе координат. ЖЭТФ 163(5), 660 (2023)
18.
О гравитационном поле чёрной дыры в синхронной системе координат В книге: Физические интерпретации теории относительности (PIRT-2023) Сборник

Presentation materials