Author(s)
Gingrich, Douglas M., Rastgoo, SaeedAbstract
We examine the geometry of a generalized uncertainty-inspired quantum black hole. The diagonal line element is not $t$-$r$ symmetric, i.e. $g_{00} \ne -1/g_{11}$, which leads to an interesting approach to resolving the classical curvature singularity. In this paper, we show, in Schwarzschild coordinates, the $r = 0$ coordinate location is a null surface which is not a transition surface or leads to a black bounce. We find the expansion of null geodesic congruences in the interior turn around then vanishes at $r = 0$, and the energy conditions are predominately violated indicating a repulsive gravitational core. In addition, we show that the line element admits a wormhole solution which is not traversable, and the black hole at its vanishing horizon radius could be interpreted as a remnant.
Figures
Metric components for the GUP-modified black hole with $m = 1$, $Q_b = 0.1$, $Q_c = 10^{-6}$ (solid lines) and the classical black hole with $m = 1$ (dashed lines).
: Radial geodesics with $E = 1$.
: Expansion scalars.
: Exterior.
: Interior.
Density and pressure combinations needed to determine the energy conditions for $m > \sqrt{Q_b}/2$ with $m = 1, Q_b = 0.1$, and $Q_c = 10^{-6}$.
: Radial geodesics with $E=4$.
: Expansion scalars.
: Carter-Penrose diagram.
: GUP wormhole with $m=1$, $Q_b = 5$, and $Q_c = 10^{-6}$.
Density and pressure combinations needed to determine the energy condition for $m < \sqrt{Q_b}/2$ with $m = 1, Q_b = 5$, and $Q_c = 10^{-6}$.
: Temperature, $T$.
: Heat capacity, $C_V$.
Entropy and area versus mass for $Q_b = 0.1$ and $Q_c = 10^{-6}$. Also shown is the classical entropy.
Tortoise coordinate $r_*$ versus $r$. Discontinuities appear at $r = r_h$ and $r = 0$.
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