A non-expanding horizon (NEH) is an enclosed null surface whose intrinsic structure is preserved. An NEH is the geometric prototype of an isolated horizon which describes a black hole in equilibrium with its exterior from the quasilocal perspective. It is based on the concept and geometry of NEHs that the two quasilocal definitions of black holes, weakly isolated horizons and isolated horizons, are developed.
A three-dimensional submanifold ∆ is defined as a generic (rotating and distorted) NEH if it respects the following conditions:[1] [2] [3]
(i) ∆ is null and topologically
S2 x R
l
\displaystyle\theta(l):=\hat{h}ab\hat{\nabla}alb
Tab
Va:=-T
| a | |
| b |
lb
VaVa\leq0
la
Condition (i) is fairly trivial and just states the general fact that from a 3+1 perspective[4] an NEH ∆ is foliated by spacelike 2-spheres ∆'=S2, where S2 emphasizes that ∆' is topologically compact with genus zero (
g=0
\theta(l)=0
Note: In this article, following the convention set up in refs., "hat" over the equality symbol
\hat=
\hathab
\hat\nabla
| a\nabla | |
| :=n | |
| a |
Now let's work out the implications of the definition of NEHs, and these results will be expressed in the language of NP formalism with the convention
\{(-,+,+,+);
| an | |
| l | |
| a=-1, |
| a\bar{m} | |
| m | |
| a=1\} |
\{(+,-,-,-);
| an | |
| l | |
| a=1, |
| a\bar{m} | |
| m | |
| a=-1\} |
la
\kappa:=-mal
| b\nabla | |
| b |
la\hat{=}0
Im(\rho)=Im(-ma\bar{m}b\nablabla)\hat{=}0
\theta(l)
la
\theta(l)\hat{=}0
Re(\rho)=Re(-ma\bar{m}b\nablabla)=-
| 1 | |
| 2 |
\theta(l)\hat{=}0
(1)
| ||||
| D\rho=\rho |
Rablalb\hat{=}0,
it follows that on ∆
(2) \sigma\bar{\sigma}+
| 1 | |
| 2 |
Rablalb\hat{=}0,
where
\sigma:=-mbma\nablaalb
Rabla
| b=R | |
| l | |
| ab |
la
| ||||
| l |
Rgablalb=8\piTablalb
c=G=1
Rablalb
\sigma\bar{\sigma}
\sigma\bar{\sigma}
Rablalb
\sigma\hat{=}0
Rablalb\hat{=}0
(3) \kappa\hat{=}0, Im(\rho)\hat{=}0, Re(\rho)\hat{=}0, \sigma\hat{=}0, Rablalb\hat{=}0.
Thus, the isolated horizon ∆ is nonevolutional and all foliation leaves ∆'=S2 look identical with one another. The relation
Rablalb=8\pi ⋅ Tablalb=8\pi ⋅
| a | |
| T | |
| b |
lb ⋅ la\hat{=}0
| a | |
| -T | |
| b |
lb
la
Rablb
la
| a | |
| -T | |
| b |
lb\hat{=}cla
Rab
| b\hat{=}cl | |
| l | |
| a |
c\inR
\Phi00:=
| 1 | |
| 2 |
Rabla
| ||||
| l |
lblb\hat{=}0
\Phi01=\overline{\Phi10
(4) Rab
| b\hat{=}cl | |
| l | |
| a, |
\Phi00\hat{=}0, \Phi10=\overline{\Phi01
\{\Phi00,\Phi01,\Phi10\}
\Psii (i=0,1,3,4)
\Psi2
\Phiij
(5) D\sigma=\sigma(\rho+\bar\rho)+\Psi0=-2\sigma\theta(l)+\Psi0,
or the NP field equation on the horizon
(6) D\sigma-\delta\kappa=(\rho+\bar{\rho})\sigma+(3\varepsilon-\bar{\varepsilon})\sigma-(\tau-\bar{\pi}+\bar{\alpha}+3\beta)\kappa+\Psi0\hat{=}0,
it follows that
\Psi0:=Cabcdlamblcmd\hat{=}0
(7) \delta\rho-\bar{\delta}\sigma=\rho(\bar{\alpha}+\beta)-\sigma(3\alpha-\bar{\beta})+(\rho-\bar{\rho})\tau+(\mu-\bar{\mu})\kappa-\Psi1+\Phi01\hat{=}0
implies that
\Psi1:=Cabcdlanblcmd\hat{=}0
(8) \Psi0\hat{=}0, \Psi1\hat{=}0,
which means that, geometrically, a principal null direction of Weyl's tensor is repeated twice and
la
\Psi0
\Psi1
For a better understanding of the previous section, we will briefly review the meanings of relevant NP spin coefficients in depicting null congruences.[11] The tensor form of Raychaudhuri's equation[12] governing null flows reads
(9) l{L}\ell\theta(l)=-
| 1 | |
| 2 |
| 2+\tilde{\kappa} | |
| \theta | |
| (l) |
\theta(l)-\sigmaab\sigmaab+\tilde{\omega}ab\tilde{\omega}ab-Rablalb,
where
\tilde{\kappa}(l)
\tilde{\kappa}(l)lb:=la\nablaalb
(10) \theta(l)=-(\rho+\bar\rho)=-2Re(\rho), \theta(n)=\mu+\bar\mu=2Re(\mu),
(11) \sigmaab=-\sigma\barma\barmb-\bar\sigmamamb,
(12) \tilde{\omega}ab=
| 1 | |
| 2 |
(\rho-\bar\rho)(ma\barmb-\barmamb)=Im(\rho) ⋅ (ma\barmb-\barmamb),
where Eq(10) follows directly from
\hat{h}ab=\hat{h}ba=mb\barma+\barmbma
(13) \theta(l)=\hat{h}ba\nablaa
| b\bar | |
| l | |
| b=m |
| a\nabla | |
| m | |
| a |
lb+\barmb
| a\nabla | |
| m | |
| a |
lb=mb\bar\deltalb+\barmb\deltalb=-(\rho+\bar\rho),
(14) \theta(n)=\hat{h}ba\nablaanb=\barmb
| a\nabla | |
| m | |
| a |
| b\bar | |
| n | |
| b+m |
| a\nabla | |
| m | |
| a |
nb=\barmb\delta
| b\bar | |
| n | |
| b+m |
\deltanb=\mu+\bar\mu.
Moreover, a null congruence is hypersurface orthogonal if
Im(\rho)=0
Vacuum NEHs on which
\{\Phiij\hat{=}0,Λ\hat{=}0\}
Λ\hat{=}0
(15) Tab=
| 1 | |
| 4\pi |
(Fac
| c | ||
| F | - | |
| b |
| 1 | |
| 4 |
gabFcdFcd),
where
Fab
Fab=-Fba
| a | |
| F | |
| a=0 |
Tab
| a | |
| T | |
| a=0 |
Fab
\phii
The boundary conditions derived in the previous section are applicable to generic NEHs. In the electromagnetic case,
\Phiij
(16) \Phiij=2\phii\overline{\phij}, i,j\in\{0,1,2\},
where
\phii
\Phi00=0
(17) D\rho
| 2+\sigma\bar{\sigma})+(\varepsilon+\bar{\varepsilon})\rho-\bar{\kappa}\tau-(3\alpha+\bar{\beta}-\pi)\kappa+\Phi | |
| -\bar{\delta}\kappa=(\rho | |
| 00 |
\hat{=}0
as
\kappa\hat{=}\rho\hat{=}\sigma=0
(18) \Phi00\hat{=}0 \Leftrightarrow 2\phi0\overline{\phi0}\hat{=}0 ⇒ \phi0=\overline{\phi0}\hat{=}0.
It follows straightforwardly that
(19) \Phi01=\overline{\Phi10
These results demonstrate that, there are no electromagnetic waves across (
\Phi00
\Phi01
\Phiij=2\phii\overline{\phij}
\Phiij=Tr(\digammai\bar{\digamma}j)
\digammai(i\in\{0,1,2\}
Usually, null tetrads adapted to spacetime properties are employed to achieve the most succinct NP descriptions. For example, a null tetrad can be adapted to principal null directions once the Petrov type is known; also, at some typical boundary regions such as null infinity, timelike infinity, spacelike infinity, black hole horizons and cosmological horizons, tetrads can be adapted to boundary structures. Similarly, a preferred tetrad adapted to on-horizon geometric behaviors is employed in the literature to further investigate NEHs.
As indicated from the 3+1 perspective from condition (i) in the definition, an NEH ∆ is foliated by spacelike hypersurfaces ∆'=S2 transverse to its null normal along an ingoing null coordinate
v
v
| 2 | |
| S | |
| v |
v=constant
{}\Delta={}\Delta'x[vo,v
| 2[v | |
| o,v |
1]
v
na
na=-dv
la
| 2 | |
| S | |
| v |
| an | |
| l | |
| a=-1 |
Dv=1
\{la,na\}
\{la,na\}
\{ma,\bar{m}a\}
| 2 | |
| S | |
| v |
\{la,na\}
l{L}\ellm\hat{=}l{L}\ell\bar{m}\hat{=}0
Now let's check the consequences of this kind of adapted tetrad. Since
(20) l{L}\ellm=[\ell,m]\hat{=}0 ⇒ \deltaD-D\delta=(\bar{\alpha}+\beta-\bar{\pi})D+\kappa\Delta-(\bar{\rho}+\varepsilon-\bar{\varepsilon})\delta-\sigma\bar{\delta}\hat{=}0,
with
\kappa\hat{=}\rho\hat{=}\sigma\hat{=}0
(21) \pi\hat{=}\alpha+\bar{\beta}, \varepsilon\hat{=}\bar{\varepsilon}.
Also, in such an adapted frame, the derivative
l{L}\bar{m
{}\Delta={}\Delta'x[vo,v
| 2[v | |
| o,v |
1]
(22) l{L}\bar{m
the coefficients for the directional derivatives
D
(23) \bar{\mu}\hat{=}\mu, l{L}\bar{m
so the ingoing null normal field
na
Im(\mu)=Im(\bar{m}a
| b\nabla | |
| m | |
| b |
na)=0
2\mu=2Re(\mu)
\theta(n)
So far, the definition and boundary conditions of NEHs have been introduced. The boundary conditions include those for an arbitrary NEH, specific characteristics for Einstein-Maxwell (electromagnetic) NEHs, as well as further properties in an adapted tetrad. Based on NEHs, WIHs which have valid surface gravity can be defined to generalize the black hole mechanics. WIHs are sufficient in studying the physics on the horizon, but for geometric purposes, stronger restrictions can be imposed to WIHs so as to introduce IHs, where the equivalence class of null normals
[\ell]
l{D}