Kerr metric...
The effects of angular momentum on Hawking radiation in physical units (S.I.):
[tex]\boxed{T_H = 2 \left(1 + \frac{1}{\sqrt{(1 - a^2)} \right)^{-1}} \frac{\hbar c^3}{8 \pi G k_b m} \leq \frac{\hbar c^3}{8 \pi G k_b m}}[/tex]
Kerr metric angular momentum:
[tex]\alpha = \frac{J}{mc}[/tex]
Radii for the dual outer and inner horizons in physical units (S.I.):
[tex]{r_{\pm} = r_g \left[1 \pm \sqrt{(1 - a^2)}\right][/tex]
Ergosphere radius:
[tex]r_{e} = r_g \left[1 + \sqrt{(1 - a^2 \cos^{2} \theta)}\right][/tex]
Radii for the dual outer and inner horizons in physical units (S.I.):
[tex]r_{\pm} = \frac{r_{s} \pm \sqrt{r_{s}^{2} - 4\alpha^{2}}}{2}[/tex]
Ergosphere radius:
[tex]r_{e} = \frac{r_{s} + \sqrt{r_{s}^{2} - 4\alpha^{2} \cos^{2}\theta}}{2}[/tex]
[tex]r_s = 2 \cdot r_g[/tex]
Establishing the equations between the Kerr metric angular momentum terms [tex]\alpha[/tex] and [tex]a[/tex] for the inner horizon radius:
[tex]r_{-} = \frac{1}{2} \left(2 r_g - \sqrt{(2 r_g)^{2} - 4 \alpha^{2}} \right) = r_g \left[1 - \sqrt{(1 - a^2)}\right][/tex]
Solving for [tex]a[/tex] for the inner horizon radius:
[tex]\boxed{a = \frac{\alpha}{r_g}}[/tex]
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Reference:
Kerr Metric - Important surfaces - Wikipedia