On exact analytical solution of Einstein-Maxwell-scalar field
equations

TURIMOV, Bobur, Bobomurat AHMEDOV and Zdeněk STUCHLÍK. On exact analytical solution of Einstein-Maxwell-scalar field equations. Physics of the Dark Universe. Netherlands, 2021, vol. 33, September, p. "100868-"-"100868-8", 8 pp. ISSN 2212-6864. Available from: https://dx.doi.org/10.1016/j.dark.2021.100868.

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TY  - JOUR
ID  - 57547
AU  - Turimov, Bobur - Ahmedov, Bobomurat - Stuchlík, Zdeněk
PY  - 2021
TI  - On exact analytical solution of Einstein-Maxwell-scalar field equations
JF  - Physics of the Dark Universe
VL  - 33
IS  - September
SP  - "100868-"-"100868-8"
EP  - "100868-"-"100868-8"
SN  - 22126864
KW  - Einstein-Maxwell-scalar equations;Exact solutions;Curvature invariants;Naked singularity;Geodesic motion
UR  - https://www.sciencedirect.com/science/article/pii/S2212686421000984?via%3Dihub
N2  - The exact analytical solution of Einstein-Maxwell-scalar (EMS) field equations has been explored which covers several well-known solutions such as the Reissner-Nordstrom, Schwarzschild-MOG (Modified Gravity), Janis-Newman-Winicour, and Schwarzschild solutions. It has been assumed that the interactions between the tensor, vector, and scalar fields are negligible. The newly obtained solution is characterized by three free parameters as the total mass M, electric (magnetic) charge Q(e) (Q(m)), and scalar charge C (or n parameter) of the gravitational compact object. It is also shown that dual solution for the vector potential A(phi) = Q(m) cos theta is satisfied by the EMS field equations and the electric charge can be safely replaced by magnetic charge Q(m). Finally, we have studied curvature invariants and test particle motion around the gravitational source described the obtained new spacetime metric. We have also provided analysis of degeneracy values of spin parameter of the rotating Kerr black hole and charge parameter of compact object described by the new spacetime metric through comparison of radii of ISCO, photonsphere and energy efficiency. It is shown that new black hole solution in Einstein-Maxwell-scalar field theory can mimic spin parameter of the Kerr black hole up to a(*) less than or similar to 0.6 while the astrophysical black hole' observations that it reaches up to a(*) less than or similar to 0.99. Consequently, one may conclude that the obtained new black hole solution can be considered as realistic candidate for the astrophysical black holes with a(*) less than or similar to 0.6.
ER  -

Basic information
Original name	On exact analytical solution of Einstein-Maxwell-scalar field equations
Authors	TURIMOV, Bobur (860 Uzbekistan, belonging to the institution), Bobomurat AHMEDOV (860 Uzbekistan) and Zdeněk STUCHLÍK (203 Czech Republic, belonging to the institution).
Edition	Physics of the Dark Universe, Netherlands, 2021, 2212-6864.

Other information
Original language	English
Type of outcome	Article in a journal
Field of Study	10308 Astronomy
Country of publisher	Netherlands
Confidentiality degree	is not subject to a state or trade secret
WWW	URL
RIV identification code	RIV/47813059:19630/21:A0000141
Organization unit	Institute of physics in Opava
Doi	http://dx.doi.org/10.1016/j.dark.2021.100868
UT WoS	000704383100031
Keywords in English	Einstein-Maxwell-scalar equations;Exact solutions;Curvature invariants;Naked singularity;Geodesic motion
Tags	2022, FÚ, RIV22, SGS-12-2019
Tags	International impact, Reviewed
Changed by	Changed by: Mgr. Pavlína Jalůvková, učo 25213. Changed: 28/3/2022 11:33.

Abstract

The exact analytical solution of Einstein-Maxwell-scalar (EMS) field equations has been explored which covers several well-known solutions such as the Reissner-Nordstrom, Schwarzschild-MOG (Modified Gravity), Janis-Newman-Winicour, and Schwarzschild solutions. It has been assumed that the interactions between the tensor, vector, and scalar fields are negligible. The newly obtained solution is characterized by three free parameters as the total mass M, electric (magnetic) charge Q(e) (Q(m)), and scalar charge C (or n parameter) of the gravitational compact object. It is also shown that dual solution for the vector potential A(phi) = Q(m) cos theta is satisfied by the EMS field equations and the electric charge can be safely replaced by magnetic charge Q(m). Finally, we have studied curvature invariants and test particle motion around the gravitational source described the obtained new spacetime metric. We have also provided analysis of degeneracy values of spin parameter of the rotating Kerr black hole and charge parameter of compact object described by the new spacetime metric through comparison of radii of ISCO, photonsphere and energy efficiency. It is shown that new black hole solution in Einstein-Maxwell-scalar field theory can mimic spin parameter of the Kerr black hole up to a(*) less than or similar to 0.6 while the astrophysical black hole' observations that it reaches up to a(*) less than or similar to 0.99. Consequently, one may conclude that the obtained new black hole solution can be considered as realistic candidate for the astrophysical black holes with a(*) less than or similar to 0.6.

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On exact analytical solution of Einstein-Maxwell-scalar field equations

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