Rong-Jia Yang^,1,2,3,?, He Gao¹, Yao-Guang Zheng¹, Qin Wu⁴1 College of Physical Science and Technology, Hebei University, Baoding 071002, China
2 Hebei Key Lab of Optic-Electronic Information and Materials, Hebei University, Baoding 071002, China
3 National-Local Joint Engineering Laboratory of New Energy Photoelectric Devices, Hebei University, Baoding 071002, China
4 School of Information Engineering, Guangdong Medical University, Dongguan 523808, China

Corresponding authors: ^?E-mail:yangrongjia@tsinghua.org.cn

Received:2018-10-15Online:2019-05-1

Fund supported:

National Natural Science Foundation of China under Grant.11273010 the Hebei Provincial Outstanding Youth Fund under Grant.A2014201068 the Outstanding Youth Fund of Hebei University under Grant.2012JQ02 Midwest Universities Comprehensive Strength Promotion Project

Abstract
We formulate and solve the problem of spherically symmetric, steady state, adiabatic accretion onto a Schwarzschild-like black hole obtained recently. We derive the general analytic expressions for the critical points, the critical velocity, the critical speed of sound, and subsequently the mass accretion rate. The case for polytropic gas is discussed in detail. We find the parameter characterizing the breaking of Lorentz symmetry will slow down the mass accretion rate, while has no effect on the gas compression and the temperature profile below the critical radius and at the event horizon.
Keywords： accretion;mass accretion rate;Lorentz breaking;Schwarzschild-like black hole


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Rong-Jia Yang, He Gao, Yao-Guang Zheng, Qin Wu. Effects of Lorentz Breaking on the Accretion onto a Schwarzschild-like Black Hole. [J], 2019, 71(5): 568-572 doi:10.1088/0253-6102/71/5/568

1 Introduction

Accretion of matter onto black hole is the most likely scenario to explain the high energy output from active galactic nuclei and quasars, which is an important phenomenon of long-standing interest to astrophysicists. Pressure-free gas dragged onto a massive central object was first considered in Refs. ^[1-2], which was generalized to the case of the spherical accretion of adiabatic fluids onto astrophysical objects.^[3] In the framework of general relativity the steady-state spherical symmetric flow of matter into or out of a condensed object was examined by Michel.^[4] Since then accretion has been an extensively studied topic in the literature, including accretion onto a Schwarzschild black hole,^[5-6] onto a Reissner-Nordstrom black hole,^[4,7-9] onto a Kerr-Newman black hole,^[10-12] onto a Kiselev black hole,^[13] and onto a black hole in a string cloud background,^[14] onto cosmological black holes or onto Schwarzschild-(anti-)de Sitter spacetimes.^[15-18] Quantum gravity effects of accretion onto a Schwarzschild black hole were considered in the context of asymptotically safe scenario.^[19] An exact solution was obtained for dust shells collapsing towards a black hole,^[20] which was generalized to the case when the tangential pressure is taken into account.^[21] Analytic solutions for accretion of a gaseous medium with an adiabatic equation of state ($P=\rho$) were obtained for a moving Schwarzschild black hole, for a moving Kerr back hole,^[22] and for a moving Reissner-Nordstr\"{o}m black hole.^[23]

An interesting study of higher dimensional accretion onto TeV black holes was discussed in the Newtonian limit.^[24] The accretion of phantom matter onto 5-dimensional charged black holes was studied in Ref. ^[25]. The accretion of phantom energy onto 5-dimensional extreme Einstein-Maxwell-Gauss-Bonnet black hole was investigated in Ref. ^[26]. Accretions were analyzed in higher-dimensional Schwarzschild black hole^[27] and in higher-dimensional Reissner-Nordstr\"{o}m black hole.^[28-29] Accretions of Dark Matter and Dark Energy onto ($n+2$)-dimensional Schwarzschild Black Hole and Morris-Thorne wormhole was considered in Ref. ^[30]. We will determine analytically the critical points, the critical fluid velocity and the critical sound speed, and subsequently the mass accretion rate. More interesting, we will investigate whether the parameter characterizing the breaking of Lorentz symmetry has effects on the accretion.

The organization of this paper is as follows. In Sec. 2, we will present the fundamental equations for the accretion of matter onto a Schwarzschild-like black hole. In Sec. 3, we will consider the critical points and the conditions the critical points must satisfy. In Sec. 4, we will discuss the case of polytropic gas in detail as an application. Finally, we will briefly summarize and discuss our results in Sec. 5.

2 Basic Equations for Accretion

A static and spherically symmetric exact solution of the Einstein equations, called Schwarzschild-like black hole, in the presence of a spontaneous breaking of Lorentz symmetry because of the nonzero vacuum expectation value of the bumblebee field was obtained in Ref. ^[31]. The geometry of Schwarzschild-like black hole is given by the following line element

(1)$ {\rm d}s^{2} =-\Bigl(1-\frac{2M}{r}\Bigr){\rm d}t^{2} +(1+l)\Bigl(1-\frac{2M}{r}\Bigr)^{-1}{\rm d}r^{2} \\ +r^{2}{\rm d}\theta^{2}+r^{2} \sin^{2}\theta {\rm d}\phi^{2} , $
where $l$ is a constant characterizing the breaking of Lorentz symmetry and $M$ is the mass of the black hole. We chose the unit system as $G=c=1$ throughout the paper. It is easy to see that the horizon of black hole is at $r_{{H}}=2M$.

We consider a static radial matter flow onto the black hole without back-reaction. The flow is an ideal fluid, which is approximated by the following energy momentum tensor

(2)$ T^{\alpha\beta}=(\rho+p)u^{\alpha}u^{\beta} +pg^{\alpha\beta} ,$
where $\rho $ is the proper energy density and $p$ is the proper pressure of the fluid. $u^{\alpha}={\rm d}x^{\alpha}/{\rm d}s$ is the 4-velocity of the fluid, which obeys the normalization condition $u^{\alpha}u_{\alpha}=-1$.

We define the radial component of the four-dimensional velocity as $\upsilon(r)=u'={{\rm d}r}/{{\rm d}s}$. Since the velocity component is zero for $\alpha>1$, we get from the normalization condition

(3)$ (u^{0})^{2}=\frac{(1+l)\upsilon^{2}+1-{2M}/{r}} {\left(1-{2M}/{r}\right)^{2}} .$
If ignoring the self-gravity of the flow, one can define baryon numbers density $n$ and numbers flow $J^{\alpha}=nu^{\alpha}$ in the flow's local inertial frame. Assuming that no particles are generated or disappeared, then the number of particles is conserved, we have

(4)$\nabla_{\alpha}J^{\alpha}=\nabla_{\alpha}(nu^{\alpha})=0 ,$
where $\nabla_{\alpha}$ represents covariant derivative with respect to the coordinate $x^{\alpha}$. For the metric (1),

the equation (4) can be rewritten as

(5)$ \frac{1}{r^{2}}\frac{{\rm d}}{{\rm d}r}\left( r^{2}n\upsilon\right)=0 , $
which for a perfect fluid gives the integration as

(6)$ r^{2}n\upsilon=C_1 , $
where $C_1$ is an integration constant. Integrating Eq. (5) over four-dimensional volume and multiplying with the mass

of each particle, $m$, we have

(7)$ \dot{M}=4\pi r^{2}mn\upsilon ,$
where $\dot{M}$ is an integration constant, which has the dimension of mass per unit time. This is the Bondi mass accretion rate actually. Ignoring the back-reaction, the $\beta=0$ component of the energy-momentum conservation, $\nabla_{\alpha}T^{\alpha}_{\beta}=0$, gives for spherical symmetry and steady-state flow

(8)$ \frac{1}{r^{2}}\frac{{\rm d}}{{\rm d}r}\Bigl[r^{2} (\rho+p)\upsilon\sqrt{1-\frac{2M}{r}+(1+l) \upsilon^{2}}\Bigr]=0 , $
which can be integrated as

(9)$ r^{2}(\rho+p)\upsilon\sqrt{1-\frac{2M}{r} +(1+l)\upsilon^{2}}=C_2 ,$
where $C_2$ is an integration constant. Dividing Eqs. (9) and (6) and then squaring, we derive

(10)$ \Bigl(\frac{\rho+p}{n}\Bigr)^{2}\Bigl[1 -\frac{2M}{r}+(1+l)\upsilon^{2}\Bigr]= \Bigl(\frac{\rho_{\infty}+p_{\infty}}{n_{\infty}}\Bigr)^{2} .$
The $\beta=1$ component of the energy-momentum conservation, $\nabla_{\alpha}T^{\alpha}_{\beta}=0$, yields

(11)$ (1+l)\upsilon\frac{{\rm d}\upsilon}{{\rm d}r}= -\frac{{\rm d}p}{{\rm d}r}\frac{1-{2M}/{r}+(1+l) \upsilon^{2}}{\rho+p}-\frac{M}{r^{2}} .$
Equations (7) and (10) are the basic conservation equations for the material flow onto a four-dimensional schwarzschild-like black hole (1) when the back-reaction of matter is ignored.

3 Conditions for Critical Accretion

In this section, we consider the conditions for critical accretion. In the local inertial rest frame of the fluid, the conservation of mass-energy for adiabatic flow without entropy generation is governed by

(12)$ 0=T{\rm d}s={\rm d}\Bigl(\frac{\rho}{n}\Bigr)+p{\rm d}\Bigl(\frac{1}{n}\Bigr) , $
from which we can get the following relationship

(13)$ \frac{{\rm d}\rho}{{\rm d}n}=\frac{\rho+p}{n} . $
Using this equation, we define the speed of adiabatic sound as

(14)$ a^{2}\equiv\frac{{\rm d}p}{{\rm d}\rho}=\frac{n}{\rho+p}\frac{{\rm d}p}{{\rm d}n} .$
Differentiating Eqs. (6) and (11) with respect to $r$, which gives, respectively

(15)$ \frac{1}{\upsilon}\upsilon '+\frac{1}{n}n'=-\frac{2}{r} , $
(16)$ (1+l)\upsilon\upsilon '+\Bigl[1-\frac{2M}{r}+(1+l)\upsilon^{2} \Bigr]a^{2}\frac{n'}{n}=-\frac{M}{r^{2}} , $
where the prime represents a derivative with respect to $r$. From these equations we get the following system

(17)$ \upsilon'=\frac{N_{1}}{N} , $
(18)$n'=-\frac{N_{2}}{N} ,$
where

(19)$ N_{1}=\frac{1}{n}\Bigl\{\Bigl[1-\frac{2M}{r} +(1+l)\upsilon^{2}\Bigr]\frac{2a^{2}}{r} -\frac{M}{r^{2}}\Bigr\} ,$
(20)$ N_{2}=\frac{1}{\upsilon}\Bigl[\frac{2(1+l) \upsilon^{2}}{r}-\frac{M}{r^{2}}\Bigr] ,$
(21)$ N=\frac{(1+l)\upsilon^{2}-[1-{2M}/{r} +(1+l)\upsilon^{2}]a^{2}}{n\upsilon} .$
For large values of $r$, we require the flow to be subsonic, that is $\upsilon<a$. Because the speed of sound is always less than the speed of light, $a<1$, then we have $\upsilon^2\ll 1$. The equation (21) can be approximated as

(22)$ N\approx\frac{(1+l)\upsilon^{2}-a^{2}}{n\upsilon} , $
and since $0<l\ll 1$ and $v<0$, we have $N>0$ as $r\rightarrow\infty$. In the event horizon, $r_{{H}}=2M$, we can get

(23)$ N=\frac{(1+l)\upsilon^{2}(1-a^{2})}{n\upsilon} . $
Under the constraint of causality, $a^{2}<1$, we have $N<0$. Therefore, there must exist critical points $r_{{c}}$ where $r_{{H}}<r_{{c}}<\infty$, at which $N=0$. The flow must pass the critical points outside the horizon, to avoid the appearance of discontinuity in the flow, we must require $N=N_{1}=N_{2}=0$ at $r=r_{\rm {c}}$, namely

(24)$ N_{1}=\frac{1}{n_{ {c}}}\Bigl\{\Bigl[1-\frac{2M}{r_{ {c}}}+(1+l)\upsilon_{ {c}}^{2}\Bigr] \frac{2a_{ {c}}^{2}}{r_{ {c}}}-\frac{M}{r_{ {c}}^{2}}\Bigr\}=0 ,$
(25)$ N_{2}=\frac{1}{\upsilon_{ {c}}}\Bigl[\frac{2(1+l)\upsilon_{{c}}^{2}}{r_{{c}}}- \frac{M}{r_{ {c}}^{2}}\Bigr]=0 , $
(26)$ N=\frac{(1+l)\upsilon_{{c}}^{2}-\Bigl[1-({2M}/{r_{ {c}}})+(1+l) \upsilon_{{c}}^{2}\Bigr]a_{ {c}}^{2}}{n_{ {c}}\upsilon_{ {c}}}=0 , $
where $a_{{c}}\equiv a(r_{{c}})$, $\upsilon_{{c}}\equiv\upsilon(r_{{c}})$, etc. From Eqs. (24), (25), and (26), we obtain the radial velocity, the speed of sound at the critical points, and the critical radius, respectively

(27)$ \upsilon_{{c}}^{2}=\frac{(2r_{{c}}-3M)a^{2}_{{c}}}{2(1+l)r_{{c}}}=\frac{M}{2(1+l)r_{{c}}}, $
(28)$ a_{{c}}^{2}=\frac{M}{2r_{{c}}-3M} ,$
(29)$ r_{{c}}=\frac{(3a^{2}_{{c}}+1)M}{2a^{2}_{{c}}} .$
For $\upsilon_{{c}}^{2}\geq 0$ and $a_{{c}}^{2}\geq 0$, Eqs. (17) and (18) exist acceptable solutions, therefore we have

(30)$ \upsilon_{{c}}^{2}=\frac{M}{2(1+l)r_{{c}}}\geq 0 ,\quad a_{{c}}^{2}=\frac{M}{2r_{{c}}-3M}\geq 0 , $
from which we can obtain the conditions satisfied by the critical points

(31)$ r_{{c}}\geq\frac{3}{2}M . $
This equation can make Eqs. (27) and (28) exist physical solutions. However, taking into account the restrictions of causality, $a^{2}_{{c}}<1$, we have $r_{{c}}>r_{{H}}$ from Eq. (29), meaning that the critical points are located at outside of the event horizon.

4 The Polytropic Solution

In this section, we will analysis the accretion rate for polytrope gas and compute the gas compression and the adiabatic temperature distribution at the outer horizon.

4.1 Accretion for Polytrope Gas

For an example to calculate explicitly $\dot{M}$, we consider the polytrope introduced in Refs. ^[2-3] with the equation of state

(32)$ p=Kn^{\gamma} ,$
where $K$ is a constant and $\gamma$ is adiabatic index satisfing $1<\gamma<{5}/{3}$. Substitute this expression into the equation for conservation of mass-energy and integrating, we can obtain

(33)$ \rho=\frac{K}{\gamma-1}n^\gamma+mn , $
where $mn$ is the rest energy density with $m$ an integration constant. With the definition of the speed of sound (14), we can rewritten the Bernoulli equation (10) as

(34)$ \Bigl(1+\frac{a^{2}}{\gamma-1-a^{2}}\Bigr)^{2} \Bigl[1-\frac{2M}{r}+(1+l)\upsilon^{2}\Bigr] \\ =\Bigl(1+\frac{a_{\infty}^{2}}{\gamma-1-a_{\infty}^{2}} \Bigr)^{2} .$
According to the critical radial velocity (27) and the critical speed of sound (28), the equation (34) must satisfy the condition at the critical point $r_{{c}}$,

(35)$ (1+3a_{{c}}^{2})\Bigl(1-\frac{a_{{c}}^{2}} {\gamma-1}\Bigr)^{2}=\Bigl(1-\frac{a_{\infty}^{2}} {\gamma-1}\Bigr)^{2} . $
Since the baryons are still non-relativistic for $r_{{c}}<r<\infty$, one can expect that $a^{2}<a_{c}^{2}\ll1$. Expanding Eq. (35) to the first order in $a_{{c}}^{2}$ and $a_{\infty}^{2}$, yields

(36)$ a_{{c}}^{2}\approx\frac{2}{5-3\gamma}a_{\infty}^{2} , $
with this equation, we can get the expression of the critical points $r_{{c}}$ in terms of the boundary condition $a_{\infty}$ and the black-hole mass $M$ as

(37)$ r_{{c}}\approx\frac{(5-3\gamma)M}{4a_{\infty}^{2}} . $
From Eqs. (14), (32), and (33), we have

(38)$ \gamma K n^{\gamma-1}=\frac{ma^{2}}{1-{a^{2}}/{(\gamma-1)}} . $
Since $a^{2}\ll 1$, we have $n\sim a^{{2}/{(\gamma-1)}}$ and

(39)$ \frac{n_{{c}}}{n_{\infty}}=\Bigl(\frac{a_{{c}}} {a_{\infty}}\Bigr)^{{2}/({\gamma-1})} .$
Since $\dot{M}$ is independent of $r$ implying from Eq. (7), it must also hold at $r=r_{{c}}$, with which we can determine the accretion rate

(40)$ \dot{M}=4\pi r^{2}m n\upsilon=4\pi r_{{c}}^{2}m n_{{c}}\upsilon_{{c}} . $
Substituting Eqs. (27), (37), and (39) into Eq. (40), we derive

(41)$ \dot{M}=4\pi \Bigl(\frac{M}{a_{\infty}^{2}}\Bigr)^{2}m n_{\infty}a_{\infty}\Bigl(\frac{1}{1+l}\Bigr) ^{{1}/{2}} \Bigl(\frac{1}{2}\Bigr)^{{(\gamma+1)}/{2(\gamma-1)}} \\ \times\Bigl(\frac{5-3\gamma}{4}\Bigr)^{{(3\gamma-5)}/{2(\gamma-1)}} .$
For $l=0$, Eq. (41) reduces to the results in Schwarzschild black hole case. The parameter $l$ can slow down the mass accretion rate. For example, comparing with the total mass accretion rate, the decrease of the mass accretion rate resulting from the Lorentz breaking parameter $l$ is about $10^{-7}$ orders, for the parameter $l$ bounded as $l<10^{-13}$.^[31] This may be a valuable feature to incorporate in astrophysical applications.

4.2 Asymptotic Behavior at the Event Horizon

In the previous sections we obtained the results are valid at large distances from the black hole near the critical radius $r_{{c}}\gg r_{H}$. Now, we analyse the flow characteristics for $r_{{H}}<r\ll r_{c}$ and at the even horizon $r=r_{{H}}$.

For $r_{{H}}<r\ll r_{c}$, we obtain the fluid velocity from Eq. (34), it can be approximated as

(42)$ \upsilon^{2}\approx\frac{2M}{(1+l)r} . $
Usin Eqs. (7), (41), and (42), we can estimate the gas compression on these scales

(43)$ \frac{n(r)}{n_{\infty}}=(\frac{M}{a^{2}_{\infty}r} )^{{3}/{2}} (\frac{1}{2})^{{2\gamma}/{2(\gamma-1)}} \\ \times(\frac{5-3\gamma}{4}) ^{{(3\gamma-5)}/{2(\gamma-1)}} . $
Assuming a Maxwell-Boltzmann gas with $p=n\kappa_{{B}}T$, we get the adiabatic temperature profile by using Eqs. (32) and (43)

(44)$ \frac{T(r)}{T_{\infty}}=\Bigl(\frac{M} {a^{2}_{\infty}r}\Bigr)^{{3(\gamma-1)}/{2}} \Bigl(\frac{1}{2}\Bigr)^{\gamma} \Bigl(\frac{5-3\gamma}{4}\Bigr)^{({3\gamma-5})/{2}} . $
Near the outer horizon, the flow is supersonic, and the fluid velocity is still well approximated by Eq. (42). At the horizon $r=r_{{H}}=2M$, the flow velocity is approximately equal to $\upsilon^{2}\approx{1}/{(1+l)}$. We can derive the gas compression at the horizon by using Eqs. (7), (41), and (42)

(45)$ \frac{n_{{H}}}{n_{\infty}}=\frac{1}{a^{3}_{\infty}} \Bigl(\frac{1}{2}\Bigr)^{{(5\gamma-3)}/{2(\gamma-1)}} \Bigl(\frac{5-3\gamma}{4}\Bigr)^{{(3\gamma-5)}/ {2(\gamma-1)}} .$
Using Eqs. (32) and (45), we obtain the adiabatic temperature profile at the event horizon for a Maxwell-Boltzmann gas with $p=n\kappa_{{B}}T$

(46)$ \frac{T_{{H}}}{T_{\infty}}=\Bigl(\frac{1}{a^{3}_{\infty}} \Bigr)^{\gamma-1} \Bigl(\frac{1}{2}\Bigr)^{{(5\gamma-3)}/{2}} \Bigl(\frac{5-3\gamma}{4}\Bigr)^{{(3\gamma-5)}/{2}} . $
Equations (43), (44), (45), and (46) show that the parameter $l$ have no effects on the gas compression and the adiabatic temperature profile, so these equations are the same in Schwarzschild black hole case.

5 Conclusions and Discussions

In this paper we formulated and solved the problem of spherically symmetric, steady state, adiabatic accretion onto a Schwarzschild-like black hole in four-dimensional spacetime by using four-dimensional general relativity. We obtained the general analytic expressions for the critical points, the critical velocity of fluid, the critical speed of sound, and subsequently the mass accretion rate. We determined the physical conditions the critical points should satisfy. We obtained the explicit expressions for the gas compression and the temperature profile below the critical radius and at the event horizon. We found the parameter characterizing the breaking of Lorentz symmetry will slow down the mass accretion rate, while has no effect on the gas compression and the temperature profile below the critical radius and at the event horizon. These results are useful for feature researches.

Reference View Option By original order
By published year
By cited within times
By Impact factor

[1] F. Hoyle and R. A. Lyttleton , The Effect of Interstellar Matter on Climatic Variation, in: Mathematical Proceedings of the Cambridge Philosophical Society, Vol. 35, Cambridge University Press, Cambridge(1939) pp. 405.
[Cited within: 1]

[2] H. Bondi and F. Hoyle , Mon. Not. Roy. Astron. Soc. 104 (1944)273.
[Cited within: 2]

[3] H. Bondi , Mon. Not. Roy. Astron. Soc. 112 (1952)195.
[Cited within: 2]

[4] F. C. Michel , Astrophys. Space Sci. 15 (1972)153.
[Cited within: 2]

[5] E. Babichev, V. Dokuchaev, and Y. Eroshenko , Phys. Rev. Lett. 93 (2004)021102, arXiv:gr-qc/0402089, doi: 10.1103/PhysRevLett.93.021102.
DOI:10.1103/PhysRevLett.93.021102URLPMID:15323894 [Cited within: 1]
Abstract: Solution for a stationary spherically symmetric accretion of the relativistic perfect fluid with an equation of state $p(\rho)$ onto the Schwarzschild black hole is presented. This solution is a generalization of Michel solution and applicable to the problem of dark energy accretion. It is shown that accretion of phantom energy is accompanied with the gradual decrease of the black hole mass. Masses of all black holes tend to zero in the phantom energy universe approaching to the Big Rip.

[6] S. Gangopadhyay, R. Mandal, B. Paik , Int. J. Mod. Phys. A 33 (2018)1850084, arXiv:1703.10057, doi: 10. 1142/S0217751X18500847.
[Cited within: 1]

[7] E. Babichev, S. Chernov, V. Dokuchaev, and Yu. Eroshenko , J. Exp. Theor. Phys. 112 (2011)784, arXiv:0806.0916, doi: 10.1134/S1063776111040157.
[Cited within: 1]

[8] M. Jamil, M. A. Rashid, and A. Qadir , Eur. Phys. J. C 58 (2008)325, arXiv:astro-ph/0808.1152, doi: 10.1140/epjc/s10052-008-0761-9.
DOI:10.1140/epjc/s10052-008-0761-9URL
In the classical relativistic regime, the accretion of phantom-like dark energy onto a stationary black hole reduces the mass of the black hole. We have investigated the accretion of phantom energy onto a stationary charged black hole and have determined the condition under which this accretion is possible. This condition restricts the mass-to-charge ratio in a narrow range. This condition also challenges the validity of the cosmic-censorship conjecture since a naked singularity is eventually produced due to accretion of phantom energy onto black hole.

[9] M. E. Rodrigues and E. L. B. Junior , Astrophys. Space Sci. 363 (2018)43, arXiv:grqc/1606.04918, doi: 10.1007/s10509-018-3262-9.
[Cited within: 1]

[10] E. Babichev, S. Chernov, V. Dokuchaev, and Yu. Eroshenko , Phys. Rev. D 78 (2008)104027, arXiv:grqc/0807.0449, doi: 10.1103/PhysRevD.78.104027.
[Cited within: 1]

[11] J. A. Jimenez Madrid and P. F. Gonzalez-Diaz , Grav. Cosmol. 14 (2008)213, arXiv:astro-ph/0510051, doi: 10.1134/S020228930803002X.
DOI:10.1134/S020228930803002XURL
Abstract: This paper deals with the study of the accretion of dark energy with equation of state $p=w\rho$ onto Kerr-Newman black holes. We have obtained that when $w>-1$ the mass and specific angular momentum increase, and that whereas the specific angular momentum increases up to a given plateau, the mass grows up unboundedly. On the regime where the dominant energy condition is violated our model predicts a steady decreasing of mass and angular momentum of black holes as phantom energy is being accreted. Masses and and angular momenta of all black holes tend to zero when one approaches the big rip. The results that cosmic censorship is violated and that the black hole size increases beyond the universe size itself are discussed in terms of considering the used models as approximations to a more general descriptions where the metric is time-dependent.

[12] J. Bhadra and U. Debnath , Eur. Phys. J. C 72 (2012)1912.arXiv:1112.6154, doi: 10.1140/epjc/s10052-012-1912-6.
DOI:10.1140/epjc/s10052-012-1912-6URL [Cited within: 1]
In this work, we have studied accretion of the dark energies in new variable modified Chaplygin gas (NVMCG) and generalized cosmic Chaplygin gas (GCCG) models onto Schwarzschild and Kerr–Newman black holes. We find the expression of the critical four velocity component which gradually decreases for the fluid flow towards the Schwarzschild as well as the Kerr–Newman black hole. We also find the expression for the change of mass of the black hole in both cases. For the Kerr–Newman black hole, which is rotating and charged, we calculate the specific angular momentum and total angular momentum. We showed that in both cases, due to accretion of dark energy, the mass of the black hole increases and angular momentum increases in the case of a Kerr–Newman black hole.

[13] L. Jiao and R. J. Yang , Eur. Phys. J. C 77 (2017)356, arXiv:grqc/1605.02320, doi: 10.1140/epjc/s10052-017-4918-2.
[Cited within: 1]

[14] A. Ganguly, S. G. Ghosh, and S. D. Maharaj , Phys. Rev. D 90 (2014)064037, arXiv:grqc/1409.7872, doi: 10.1103/PhysRevD.90.064037.
DOI:10.1103/PhysRevD.90.064037URL [Cited within: 1]
DOI: http://dx.doi.org/10.1103/PhysRevD.90.064037

[15] C. Gao, X. Chen, V. Faraoni, and Y. G. Shen , Phys. Rev. D 78 (2008)024008, arXiv:grqc/0802.1298, doi: 10.1103/PhysRevD.78.024008.
[Cited within: 1]

[16] P. Mach and E. Malec , Phys. Rev. D 88 (2013)084055, arXiv:grqc/1309.1546, doi: 10.1103/PhysRevD.88.084055.
DOI:10.1103/PhysRevD.88.084055URL
In a recent paper we investigated stationary, relativistic Bondi-type accretion in Schwarzschild-(anti-)de Sitter spacetimes. Here we study their stability, using the method developed by Moncrief. The analysis applies to perturbations satisfying the potential flow condition. We prove that global isothermal flows in Schwarzschild-anti-de Sitter spacetimes are stable, assuming the test-fluid approximation. Isothermal flows in Schwarzschild-de Sitter geometries and polytropic flows in Schwarzschild-de Sitter and Schwarzschild-anti-de Sitter spacetimes can be stable, under suitable boundary conditions.

[17] P. Mach, E. Malec, and J. Karkowski , Phys. Rev. D 88 (2013)084056, arXiv:grqc/1309.1252, doi: 10.1103/ PhysRevD.88.084056.


[18] J. Karkowski , Phys. Rev. D 87 (2013)044007, arXiv:grqc/1211.3618, doi: 10.1103/PhysRevD.87.044007.
[Cited within: 1]

[19] R. Yang , Phys. Rev. D 92 (2015)084011, arXiv:grqc/1504.04223, doi: 10.1103/PhysRevD.92.084011.
[Cited within: 1]

[20] Y. Liu and S. N. Zhang , Phys. Lett. B 679 (2009)88, arXiv:grqc/0907.2574, doi: 10.1016/j.physletb.2009.07.033.
DOI:10.1016/j.physletb.2009.07.033URL [Cited within: 1]
The gravitational collapse of a star is an important issue both for general relativity and astrophysics, which is related to the well-known “frozen star” paradox. This paradox has been discussed intensively and seems to have been solved in the comoving-like coordinates. However, to a real astrophysical observer within a finite time, this problem should be discussed in the point of view of the distant rest-observer, which is the main purpose of this Letter. Following the seminal work of Oppenheimer and Snyder (1939), we present the exact solution for one or two dust shells collapsing towards a pre-existing black hole. We find that the metric of the inner region of the shell is time-dependent and the clock inside the shell becomes slower as the shell collapses towards the pre-existing black hole. This means the inner region of the shell is influenced by the property of the shell, which is contrary to the result in Newtonian theory. It does not contradict the Birkhoff's theorem, since in our case we cannot arbitrarily select the clock inside the shell in order to ensure the continuity of the metric. This result in principle may be tested experimentally if a beam of light travels across the shell, which will take a longer time than without the shell. It can be considered as the generalized Shapiro effect, because this effect is due to the mass outside, but not inside as the case of the standard Shapiro effect. We also found that in real astrophysical settings matter can indeed cross a black hole's horizon according to the clock of an external observer and will not accumulate around the event horizon of a black hole, i.e., no “frozen star” is formed for an external observer as matter falls towards a black hole. Therefore, we predict that only gravitational wave radiation can be produced in the final stage of the merging process of two coalescing black holes. Our results also indicate that for the clock of an external observer, matter, after crossing the event horizon, will never arrive at the “singularity” (i.e. the exact center of the black hole), i.e., for all black holes with finite lifetimes their masses are distributed within their event horizons, rather than concentrated at their centers. We also present a worked-out example of the Hawking's area theorem.

[21] S. X. Zhao and S. N. Zhang , Chin. Phys. C 42 (2018)085101, arXiv:grqc/1805.04056, doi: 10.1088/1674-1137/42/8/085101.
[Cited within: 1]

[22] L. I. Petrich, S. L. Shapiro, and S. A. Teukolsky , Phys. Rev. Lett. 60 (1988)1781.
[Cited within: 1]

[23] L. Jiao and R. J. Yang , JCAP 1709 (2017) 023, arXiv:grqc/1609.08298, doi: 10.1088/1475-7516/2017/09/023.
[Cited within: 1]

[24] S. B. Giddings and M. L. Mangano , Phys. Rev. D 78 (2008)035009, arXiv:hep-ph/0806.3381, doi: 10.1103/ PhysRevD. 78.035009.
[Cited within: 1]

[25] M. Sharif and G. Abbas , Mod. Phys. Lett. A 26 (2011)1731, arXiv:grqc/1106.2415, doi: 10.1142/S0217732311\-036218.
[Cited within: 1]

[26] M. Jamil and I. Hussain , Int. J. Theor. Phys. 50 (2011)465, arXiv:astro-ph.CO/1101.1583, doi: 10.1007/s10773-010-0553-5.
DOI:10.1007/s10773-010-0553-5URL [Cited within: 1]
AbstractWe have investigated the accretion of phantom energy onto a 5-dimensional extreme Einstein-Maxwell-Gauss-Bonnet (EMGB) black hole. It is shown that the evolution of the EMGB black hole mass due to phantom energy accretion depends only on the pressure and density of the phantom energy and not on the black hole mass. Further we study the generalized second law of thermodynamics (GSL) at the event horizon and obtain a lower bound on the pressure of the phantom energy.

[27] A. J. John, S. G. Ghosh, and S. D. Maharaj , Phys. Rev. D 88 (2013)104005, arXiv:grqc/1310.7831, doi: 10.1103/PhysRevD.88.104005.
DOI:10.1103/PhysRevD.88.104005URL [Cited within: 1]
We examine the steady-state spherically symmetric accretion of relativistic fluids, with a polytropic equation of state, onto a higher-dimensional Schwarzschild black hole. The mass accretion rate, critical radius, and flow parameters are determined and compared with results obtained in standard four dimensions. The accretion rate, $\stackrel{\ifmmode \dot{}\else \textperiodcentered \fi{}}{M}$, is an explicit function of the black hole mass, $M$, as well as the gas boundary conditions and the dimensionality, $D$, of the spacetime. We also find the asymptotic compression ratios and temperature profiles below the accretion radius and at the event horizon. This analysis is a generalization of Michel's solution to higher dimensions and of the Newtonian expressions of Giddings and Mangano, which consider the accretion of TeV black holes.

[28] R. J. Yang and H. Gao , arXiv:grqc/1801.07973.
[Cited within: 1]

[29] M. Sharif and S. Iftikhar , Eur. Phys. J. C 76 (2016)147, arXiv:grqc/1603.01466, doi: 10.1140/epjc/s10052-016-4001-4.
[Cited within: 1]

[30] U. Debnath , Astrophys. Space Sci. 360 (2015)40, arXiv:grqc/1502.02982.
[Cited within: 1]

[31] R. Casana, A. Cavalcante, F. P. Poulis, and E. B. Santos , Phys. Rev. D 97 (2018)104001, arXiv:grqc/1711.02273, doi: 10.1103/PhysRevD.97.104001.
[Cited within: 2]