Abstract
In this paper, we investigate the motion of a classical spinning test particle in a background of a spherically symmetric black hole based on the novel four-dimensional Einstein–Gauss–Bonnet gravity [D. Glavan and C. Lin, Phys. Rev. Lett. 124, 081301 (2020)]. We find that the effective potential of a spinning test particle in this background could have two minima when the Gauss–Bonnet coupling parameter α is nearly in a special range −8<α/M2<−2 (M is the mass of the black hole), which means a particle can be in two separate orbits with the same spin-angular momentum and orbital angular momentum, and the accretion disc could have discrete structures. We also investigate the innermost stable circular orbits of the spinning test particle and find that the corresponding radius could be smaller than the cases in general relativity.
Highlights
As the most successful gravitational theory, general relativity (GR) can explain the relation between geometry and matter
We investigated the motion of a spinning test particle in the equatorial plane of the four-dimensional novel EGB black hole
We found that the innermost stable circular orbit (ISCO) of the spinning test particle has similar behavior as the case of a spinning test particle in GR
Summary
As the most successful gravitational theory, general relativity (GR) can explain the relation between geometry and matter. [38], the authors extended the range of the GB coupling parameter for the black hole solution to −8 ≤ α/M2 ≤ 1 (M is the mass of the black hole) and investigated the shadow and ISCO of a spinless test particle. Inspired by the effects of the four-dimensional GB term and the non-vanishing spin on the motion of the test particle, it is necessary to investigate the motion of a spinning test particle and the corresponding ISCO in this novel four-dimensional EGB black hole. We will investigate the motion of a spinning test particle in the background of the novel four-dimensional EGB black hole and show how the ISCO of the spinning test particle is changed.
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