-
The KNTNdS spacetimesolves the Einstein-Maxwell equations of motion with a positive cosmological constant, namely,
$ \begin{array}{*{20}{l}} R_{\mu \nu } - \dfrac{1}{2}g_{\mu \nu } R + \dfrac{3}{l^2} g_{\mu \nu } = 2F_{\mu \alpha } F_\nu ^\alpha - \dfrac{1}{2}g_{\mu \nu } F_{\alpha \beta } F^{\alpha \beta } \,, \end{array} $
(1) where
$ F_{\mu\nu}=\partial_\mu A_\nu -\partial_\nu A_\mu $ . The vector field obeys the source free condition$ \nabla _\mu F^{\mu \nu } = 0 $ and the Bianchi identity$ \nabla _\mu F_{\alpha \beta }+\nabla _\beta F_{\mu \alpha }+\nabla _\alpha F_{\beta \mu }=0 $ . The KNTNdS spacetime metric can be expressed as$ \begin{aligned}[b] {\rm d}s^2 =& - \frac{{\Delta _r }}{{\rho ^2 }}\left( {{\rm d}t - \left( {a\Delta _x - 2nx} \right){\rm d}\phi } \right)^2 + \rho ^2 \left( {\frac{{{\rm d}r^2 }}{{\Delta _r }} + \frac{{{\rm d}x^2 }}{{\Delta _x \Delta _l }}} \right)\\ &+ \frac{{\Delta _x \Delta _l }}{{\rho ^2 }}\left( {a{\rm d}t - \left( {r^2 + a^2 + n^2 } \right){\rm d}\phi } \right)^2 \end{aligned} $
(2) where
$ \Delta_x = 1-x^2 $ ,$ \begin{aligned}[b] \Delta _r = & r^2 - 2Mr + Q^2 + a^2 - n^2 \\ &- \frac{3}{{l^2 }}\left( {\left( {a^2 - n^2 } \right)n^2 + \left( {\frac{{a^2 }}{3} + 2n^2 } \right)r^2 + \frac{{r^4 }}{3}} \right)\,, \end{aligned} $
(3) $ \begin{array}{*{20}{l}} \Delta _l = 1 + \dfrac{ax\left(4n+ax\right)}{l^2} \,, \end{array} $
(4) and
$ \rho ^2 = r^2 + (n+ax)^2 $ . It is understood that M, a, n, and Q are the mass, rotation, NUT charge, and electric charge parameters. The corresponding cosmological constant in the equation above is$ \Lambda = 3 l^{-2} $ . The accompanying vector components to solve the Einstein equations (1) are$ \begin{array}{*{20}{l}} A_\mu {\rm d}x^\mu = \dfrac{Qr}{\rho^2} \left( {\rm d}t + \left(2n x - a \Delta_x \right){\rm d}\phi\right)\,. \end{array} $
(5) It is known that multiple horizons with positive radii can exist in the KNTNdS spacetime. The largest one is acknowledged as the cosmological horizon
$ r_c $ , the outer black hole horizon is$ r_b $ , and the inner one is denoted by$ r_i $ , where$ r_c > r_b > r_i $ . The coincidence of cosmological and outer black hole horizons is known as the extremal state for the cosmological horizon, whereas another coincidence$ r_b=r_i $ is understood as the extremal configuration for black holes in KNTNdS spacetime. Some illustrations of these extremal states are given in Figs. 1, 2, and 3. These plots confirm several extremalities that can exist in the KNTNdS spacetime.Figure 1. (color online) Case
$ l=M $ . The black curves represent$ r_c=r_b $ , whereas the blue ones represent$ r_b=r_i $ .Figure 2. (color online) Case
$ l=M $ . The black curves represent$ r_c=r_b $ , whereas the blue ones represent$ r_b=r_i $ .Figure 3. (color online) Case
$ l=M $ . The black curves represent$ r_c=r_b $ , whereas the blue ones represent$ r_b=r_i $ . The dashed blue line does not exist because the case of$ a=Q=0 $ describes the Taub-NUT-de Sitter spacetime.The area of cosmological horizon can be computed using the standard formula
$ \begin{array}{*{20}{l}} A_c = \displaystyle\int\limits_{\phi = 0}^{2\pi } {\displaystyle\int\limits_{\theta = 0}^\pi {\sqrt {g_{\theta \theta } g_{\phi \phi } } {\rm d}\theta {\rm d}\phi } } = 4\pi \left( {r_c^2 + a^2 + n^2 } \right)\,, \end{array} $
(6) whereas the surface gravity associated to the cosmological horizon can be given by [16, 17]
$ \begin{array}{*{20}{l}} \kappa_c = \dfrac{{2\pi }}{{A_c }}\left. {\dfrac{{{\rm d}\Delta _r }}{{{\rm d}r}}} \right|_{r_c } \,, \end{array} $
(7) which gives
$ \begin{array}{*{20}{l}} \kappa_c = \dfrac{{\left( {r_c - M} \right) l^2 - r_c \left( {2r_c^2 + 6n^2 + a^2 } \right)}}{{\left( {r_c^2 + a^2 + n^2 } \right)l^2 }}\,. \end{array} $
(8) Accordingly, the Hawking temperature that corresponds to the cosmological horizon can be computed using the relation
$T_{\rm c} = \kappa_c/2\pi$ . The angular velocity and electric potential at the cosmological horizon can be written as$ \begin{array}{*{20}{l}} \Omega _c = \dfrac{a}{{r_c^2 + a^2 + n^2 }}\,, \end{array} $
(9) and
$ \begin{array}{*{20}{l}} \Phi _c = \dfrac{{qr_c }}{{r_c^2 + a^2 + n^2 }}\,, \end{array} $
(10) respectively.
The thermodynamics of Taub-NUT spacetime has become a lively discussion in recent years [16, 17, 24–27]. One of the proposals is to associate an entropy for the Misner string in the Taub-NUT spacetime [25]. Another is to introduce some conserved charges, i.e.,
$ \Xi = Mn $ and$ N=n $ , so the resulting first law of horizon mechanics would read [16]$ \begin{array}{*{20}{l}} \delta M = T\delta S + \Omega \delta J + \Phi \delta Q + \Omega_n \delta J_n + \Psi \delta N + \Theta \delta \Lambda \,. \end{array} $
(11) The last term in Eq. (11) represents the change of total energy inside of the cosmological horizon due to the variation of the cosmological constant. In Section 4, where we compute the microscopic formula for the entropy, Eq. (11) will be used to obtain the corresponding conjugate charge. Note that in the vanishing of
$ \delta \Lambda $ ,$ \delta N $ , and$ \delta J_n $ , this first law of horizon mechanics simply reduces to the one that is related to the Kerr-Newman black hole [28]. -
The hidden conformal symmetry can be shown from the corresponding massless test scalar field in the near region of the cosmological horizon. Here, we consider the test charged massless scalar with an equation of motion
$ \begin{array}{*{20}{l}} \left( {\nabla _\mu + {\rm i}qA_\mu } \right)\left( {\nabla ^\mu + {\rm i}qA^\mu } \right)\Psi = 0\,. \end{array} $
(12) Note that the KNTNdS spacetime possesses the stationary and axial Killing symmetry, which allows us to express the test scalar wave function to be separable in the following way:
$ \begin{array}{*{20}{l}} \Psi = {\rm e}^{ - {\rm i}\omega t + {\rm i}m\phi } X\left( x \right)R\left( r \right)\,. \end{array} $
(13) Using this ansatz, the Klein-Gordon equation above can be written as
$ \begin{aligned}[b] &\frac{1}{X\left( x \right)}\frac{\rm d}{{{\rm d}r}}\left( {\Delta _r \frac{{{\rm d}R\left( r \right)}}{{{\rm d}r}}} \right) + \frac{1}{R\left( r \right)}\frac{{\rm d}}{{{\rm d}x}}\left( {\Delta _x \Delta _l \frac{{{\rm d}X\left( x \right)}}{{{\rm d}x}}} \right)\\ +& \left\{ {\dfrac{{\left( {\left( {r^2 + a^2 + n^2 } \right)\omega + qQr - ma} \right)^2 }}{{\Delta _r }} } - \dfrac{{\left( {ax^2 + 2nx\omega - am\omega } \right)^2 }}{{\Delta _l \Delta _x }} \right\} \\ =& 0\,. \end{aligned} $
(14) It turns out that the last equation can be separated into two equations, namely, the radial part
$ \begin{aligned}[b] &\dfrac{\rm d}{{{\rm d}r}}\left( {\Delta _r \dfrac{{{\rm d}R\left( r \right)}}{{{\rm d}r}}} \right) + \left( {\dfrac{{\left( {\left( {r^2 + a^2 + n^2 } \right)\omega + qQr - ma} \right)^2 }}{{\Delta _r }} - \lambda } \right)R\left( r \right) \\ =& 0\,, \end{aligned} $
(15) and the angular one
$ \begin{array}{*{20}{l}} \dfrac{\rm d}{{{\rm d}x}}\left( {\Delta _x \Delta _l \dfrac{{{\rm d}X\left( x \right)}}{{{\rm d}x}}} \right) - \left( - \dfrac{{\left( {ax^2 + 2nx\omega - am\omega } \right)^2 }}{{\Delta _l \Delta _x }} - \lambda \right)X\left( x \right) = 0\,, \end{array} $
(16) with λ as the separable constant.
The hidden conformal symmetry is related to the radial Eq. (15) under some circumstances. However, before we proceed to show the hidden conformal symmetry, we need to consider an approximation to
$ \Delta_r $ in the radial Eq. (15) so that it can be quadratic in r. Such approximation has been repeatedly performed for the hidden conformal symmetry in the (anti)-de Sitter spacetime [13, 14, 29]. The approximation is basically a Taylor expansion for$ \Delta_r $ near the cosmological horizon radius,$ \begin{array}{*{20}{l}} \Delta _r \simeq \left. {\Delta _r } \right|_{r_c } + \left. {\dfrac{{{\rm d}\Delta _r }}{{{\rm d}r}}} \right|_{r_c } \left( {r - r_c } \right) + \left. {\dfrac{{{\rm d}^2 \Delta _r }}{{{\rm d}r^2 }}} \right|_{r_c } \dfrac{{\left( {r - r_c } \right)^2 }}{2}\,, \end{array} $
(17) that can give us
$ \begin{array}{*{20}{l}} \Delta _r \simeq K\left( {r - r_c } \right)\left( {r - r_c^* } \right)\,. \end{array} $
(18) Related to the KNTNdS spacetime (2), we have
$ \begin{array}{*{20}{l}} K = 1 - l^{ - 2} \left( {a^2 + 6n^2 + 6r_c^2 } \right)\,, \end{array} $
(19) and
$ \begin{array}{*{20}{l}} r_c^* = \dfrac{{2r_c^3 + r_c \left( {l^2 - a^2 - 6n^2 } \right) - 2Ml^2 }}{{a^2 + 6n^2 + 6r_c^2 - l^2 }}\,. \end{array} $
(20) Now let us impose the near horizon region for the test scalar, given by
$ \omega r \ll 1 $ . We also consider that the test scalar is in the low frequency,$ \omega M \ll 1 $ , and its charge is extremely small,$ qQ \ll 1 $ . Subsequently, the low frequency can be related to the conditions$ \omega a \ll 1 $ ,$ \omega Q \ll 1 $ , and$ \omega n \ll 1 $ .Under such considerations, the radial Eq. (15) can be rewritten approximately as
$ \begin{array}{*{20}{l}} \dfrac{\rm d}{{{\rm d}r}}\left( {\left( {r - r_c } \right)\left( {r - r_c^* } \right)\dfrac{{{\rm d}R}}{{{\rm d}r}}} \right) + {\dfrac{{F_1 R}}{{\left( {r - r_c } \right)}} + \dfrac{{F_2 R}}{{\left( {r - r_c^* } \right)}}} + F_3 R = 0\,, \end{array} $
(21) with
$ \begin{array}{*{20}{l}} F_1 = \dfrac{{\left( {\omega \left( {r_c^{2} + a^2 + n^2 } \right)+ qQr_c - ma } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(22) $ \begin{array}{*{20}{l}} F_2 = - \dfrac{{\left( {\omega \left( {r_c^{*2} + a^2 + n^2 } \right) + qQr_c^*- ma } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(23) and
$ \begin{array}{*{20}{l}} F_3 = \dfrac{{q^2 Q^2 -\lambda }}{{K }}\,. \end{array} $
(24) Furthermore, to show the symmetry property of Eq. (21), we consider the following conformal coordinates:
$ \begin{array}{*{20}{l}} \omega^ + = \sqrt {\dfrac{{r - r_c }}{{r - r_c^* }}} \exp \left( {2\pi T_R \phi + 2n_R t} \right)\,, \end{array} $
(25) $ \begin{array}{*{20}{l}} \omega^ + = \sqrt {\dfrac{{r - r_c }}{{r - r_c^* }}} \exp \left( {2\pi T_L \phi + 2n_L t} \right)\,, \end{array} $
(26) $ \begin{array}{*{20}{l}} \omega^0 = \sqrt {\dfrac{{r_c - r_c^* }}{{r - r_c^* }}} \exp \left( {\pi \left( {T_R + T_L } \right)\phi + \left( {n_R + n_L } \right)t} \right)\,. \end{array} $
(27) By using these coordinates, and also the notations
$ \begin{array}{*{20}{l}} \partial _{+ } = \dfrac{\partial }{{\partial \omega^ + }}\; \; ,\; \; \partial _{ - } = \dfrac{\partial }{{\partial \omega^ - }}\; \; ,\; \; \partial _{0} = \dfrac{\partial }{{\partial \omega^0 }}\,, \end{array} $
(28) one can define two copies of the
$S L(2,\mathbb{R})$ generators that read$ \begin{array}{*{20}{l}} H_{+ } = {\rm i}\partial _{+ } \,, \end{array} $
(29) $ \begin{array}{*{20}{l}} H_{0} = {\rm i}\left( {\omega^ + \partial _{k, + } + \frac{1}{2}\omega^0 \partial _{0} } \right)\,, \end{array} $
(30) $ \begin{array}{*{20}{l}} H_{- } = {\rm i}\left( {\left( {\omega^ + } \right)^2 \partial _{ + } + \omega^ + \omega^0 \partial _{0} - \left( {\omega^0 } \right)^2 \partial _{- } } \right)\,, \end{array} $
(31) and
$ \begin{array}{*{20}{l}} \bar H_{+ } = {\rm i}\partial _{ - } \,, \end{array} $
(32) $ \begin{array}{*{20}{l}} \bar H_{0} = {\rm i}\left( {\omega^ - \partial _{- } + \frac{1}{2}\omega^0 \partial _{0} } \right)\,, \end{array} $
(33) $ \begin{array}{*{20}{l}} \bar H_{- } = {\rm i}\left( {\left( {\omega^ - } \right)^2 \partial _{- } + \omega^ - \omega^0 \partial _{0} - \left( {\omega^0 } \right)^2 \partial _{ + } } \right)\,. \end{array} $
(34) The generators above satisfy the
$S L(2,\mathbb{R})$ algebra,$ \begin{array}{*{20}{l}} \left[ {H_{0} ,H_{ \pm } } \right] = \mp {\rm i} H_{ \pm }\; \; ,\; \; \left[ {H_{ + } ,H_{ - } } \right] = 2{\rm i}H_{0} \,, \end{array} $
(35) and
$ \begin{array}{*{20}{l}} \left[ {\bar H_{0} ,\bar H_{ \pm } } \right] = \mp {\rm i}\bar H_{ \pm } \; \; ,\; \; \left[ {\bar H_{ + } ,\bar H_{ - } } \right] = 2 {\rm i}\bar H_{0} \,. \end{array} $
(36) Moreover, based on the generators above, one can also construct the
$S L(2,\mathbb{R})$ Casimir operators$ {\cal H}^2 = - H_{0}^2 + \frac{1}{2}\left( {H_{ + } H_{ - } + H_{ - } H_{ + } } \right)\,, $
(37) and
$ \bar {\cal H}^2 = - \bar H_{0}^2 + \frac{1}{2}\left( {\bar H_{ + } \bar H_{ - } + \bar H_{ - } \bar H_{ + } } \right)\,. $
(38) These Casimir operators commute with all generators in the group. It turns out that although the Casimir operators
$ {\cal H}^2 $ and$ \bar{\cal H} $ are constructed by a different set of operators, they take exactly the same form in terms of the conformal coordinates$ {\cal H}^2 = \bar {\cal H}^2 = \frac{1}{4}\left( {\left( {\omega ^0 } \right)^2 \partial _{0}^2 - \omega ^0 \partial _{0} } \right) + \left( {\omega ^0 } \right)^2 \partial _{ + } \partial _{ - } $
(39) Furthermore, in terms of the coordinates
$(t,~r,~\phi)$ , the Casimir operator (39) can be written explicitly as$ \begin{aligned}[b] {\cal H}^2 =& \left( {r - r_c } \right)\left( {r - r_c^* } \right)\frac{{\partial ^2 }}{{\partial r^2 }} + \left( {2r - r_c^* - r_c } \right)\frac{\partial }{{\partial r}} \\ &+ \frac{{\left( {r_c - r_c^* } \right)}}{{r - r_c^* }}\left( {\frac{{n_L - n_R }}{{4\pi {\Xi} }}\frac{\partial }{{\partial \phi }} - \frac{{T_L - T_R }}{{4{\Xi} }}\frac{\partial }{{\partial t}}} \right)^2 \\ &- \frac{{\left( {r_c - r_c^* } \right)}}{{r - r_c }}\left( {\frac{{n_L + n_R }}{{4\pi {\Xi} }}\frac{\partial }{{\partial \phi }} - \frac{{T_L + T_R }}{{4{\Xi} }}\frac{\partial }{{\partial t}}} \right)^2 \,,\end{aligned} $
(40) where
$ \Xi = n_L T_R - n_R T_L $ . The hidden conformal symmetry is stated from the fact that the radial Eq. (21) is just the eigen equation for the Casimir operator$ {\cal H}^2 $ in Eq. (40) with the separation constant λ as the corresponding eigenvalue. In this manner, it is said that the radial Eq. (21) exhibits the$S L(2,\mathbb{R})_L \times S L(2,\mathbb{R})_R$ symmetry.In the development, the hidden conformal symmetry for the black hole/CFT correspondence was found in several pictures [28, 30]. The first one is known as the J-picture, which uses the neutral test scalar to probe the symmetry. This is actually the original proposal of hidden conformal symmetry in the Kerr/CFT correspondence [31], where the property of low frequency neutral test scalar in the near region of the Kerr black hole is explored. The second one is called the Q-picture [32], where a
$ U(1) $ internal space is introduced and the test scalar is considered to be in the state of zeroth quantum magnetic number. Subsequently, these J and Q pictures can be formulated into a single treatment known as the general picture [30], where the CFT duals are generated by the modular group$S L(2,{\mathbb Z})$ . In the following, we show that the twofold or even the general pictures of hidden conformal symmetry that are applied for the black hole horizon [28, 30] can also be found near the cosmological horizon.The J picture is obtained by considering a neutral scalar test probe in the near horizon region. This consideration yields Eq. (21), which reduces to
$ \begin{array}{*{20}{l}} \dfrac{\rm d}{{{\rm d}r}}\left( {\left( {r - r_c } \right)\left( {r - r_c^* } \right)\dfrac{{{\rm d}R}}{{{\rm d}r}}} \right) + {\dfrac{{G_1^J R}}{{\left( {r - r_c } \right)}} + \dfrac{{G_2^J R}}{{\left( {r - r_c^* } \right)}}} + G_3^J R = 0\,, \end{array} $
(41) where
$ \begin{array}{*{20}{l}} G_1^J = \dfrac{{\left( {\omega \left( {r_c^{*2} + a^2 + n^2 } \right) - ma } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(42) $ \begin{array}{*{20}{l}} G_2^J = - \dfrac{{\left( {\omega \left( {r_c^{*2} + a^2 + n^2} \right) - ma } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(43) and
$ \begin{array}{*{20}{l}} G_3^J = - \dfrac{\lambda }{K}\,. \end{array} $
(44) To have an agreement between the radial Eq. (41) with the general form (40), we need to set the corresponding parameters as
$ \begin{array}{*{20}{l}} n_R^J = 0\; \; ,\; \; n_L^J = - \dfrac{K}{{2\left( {r_c + r_c^* } \right)}}\,, \end{array} $
(45) and
$ \begin{array}{*{20}{l}} T_R^J = \dfrac{{K \left( {r_c - r_c^* } \right)}}{{4\pi a}}\; \; ,\; \; T_L^J = \dfrac{{K \left( {r_c^2 + {r_c^*}^2 + 2a^2 + 2n^2 } \right)}}{{4\pi a \left( {r_c + r_c^* } \right)}}\,. \end{array} $
(46) In this way, we have constructed the J picture hidden conformal symmetry near the cosmological horizon of the KNTNdS spacetime.
If the J-picture corresponds to the neutral scalar test field, the Q-picture can be probed by using the scalar field at
$ m=0 $ state. However, the Q-picture hidden conformal symmetry requires the existence of a$ U(1) $ internal space χ. The dependence of scalar wave Ψ with respect to this new coordinate is given by the eigen equation$ \begin{array}{*{20}{l}} \partial _\chi \Psi = {\rm i} q \Psi \,. \end{array} $
(47) Indeed, it has an analogy with the equation for the angular coordinate ϕ where the scalar probe dependence is given by
$\partial _\phi \Psi = {\rm i} m \Psi$ . For the$ m=0 $ state, the radial Eq. (21) takes the form$ \begin{array}{*{20}{l}} \dfrac{\rm d}{{{\rm d}r}}\left( {\left( {r - r_c } \right)\left( {r - r_c^* } \right)\dfrac{{{\rm d}R}}{{{\rm d}r}}} \right) + {\dfrac{{G_1^Q R}}{{\left( {r - r_c } \right)}} + \dfrac{{G_2^Q R}}{{\left( {r - r_c^* } \right)}}}+ G_3^Q R = 0\,, \end{array} $
(48) where
$ \begin{array}{*{20}{l}} G_1^Q = \dfrac{{\left( {\omega \left( {r_c^{2} + a^2 +n^2} \right) + qQr_c } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(49) $ \begin{array}{*{20}{l}} G_2^Q = - \dfrac{{\left( {\omega \left( {r_c^{*2} + a^2+n^2 } \right) + qQr_c^* } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(50) and
$ \begin{array}{*{20}{l}} G_3^Q = \dfrac{{q^2 Q^2 }}{{K^2 }}\,. \end{array} $
(51) To have an agreement between (40) and (48), the corresponding parameters should be set as
$ \begin{array}{*{20}{l}} n_L^Q = - \dfrac{{K\left( {r_c + r_c^* } \right)}}{{4 \left( {r_cr_c^* - a^2-n^2 } \right) }}\; \; ,\; \; n_R^Q =- \dfrac{{K\left( {r_c - r_c^* } \right)}}{{4 \left( {r_cr_c^* - a^2-n^2 } \right) }}\,, \end{array} $
(52) and
$ \begin{array}{*{20}{l}} T_L^Q = -\dfrac{{K \left( {r_c^2 + r_c^{*2} +2 a^2 + 2 n^2 } \right)}}{{4\pi Q\left( {r_c r_c^* - a^2 -n^2} \right)}} , T_R^Q = -\dfrac{{K \left( {r_c^2 - r_c^{*2} } \right)}}{{4\pi Q\left( {r_c r_c^* - a^2 - n^2 } \right)}}\,. \end{array} $
(53) Here, we have shown that the Q-picture of hidden conformal symmetry for the cosmological horizon of KNTNdS spacetime does exist as well.
Now let us discuss the general picture, which combines both the J and Q pictures in a single formulation. The similarity between Eqs. (41) and (48) is obvious. It then allows us to write an equation that utilizes the
$S L(2,{\mathbb Z})$ modular group, which can reduce to both Eqs. (41) and (48) for some special cases. The$S L(2,{\mathbb Z})$ modular group itself acts on the torus with coordinates$(\phi,~ \chi)$ that appear in Eqs. (41) and (48). The corresponding$S L(2,{\mathbb Z})$ transformation is given by$ \begin{array}{*{20}{l}} \left( {\begin{array}{*{20}c} {\phi '} \\ {\chi '} \\ \end{array}} \right) = \left( {\begin{array}{*{20}c} \alpha & \beta \\ \gamma & \delta \\ \end{array}} \right)\left( {\begin{array}{*{20}c} \phi \\ \chi \\ \end{array}} \right)\,. \end{array} $
(54) Intuitively, related to the new coordinates
$ \phi ' $ and$ \chi ' $ , the corresponding eigenvalues of operators${\rm i}\partial_{\phi '} $ and${\rm i}\partial_{\chi '} $ are$ m' $ and$ q' $ , respectively. Therefore, one can write the relation between the parameters$(m,~q)$ and$(m',~q')$ as$ \begin{array}{*{20}{l}} m = \alpha m' + \gamma q'\; \; ,\; \; q = \beta m' + \delta q'\,. \end{array} $
(55) In terms of
$(m',~q')$ parameters, the radial Eq. (21) can be rewritten as$ \begin{array}{*{20}{l}} \dfrac{\rm d}{{\rm d}r}\left( {\left( {r - r_c } \right)\left( {r - r_c^* } \right)\dfrac{{{\rm d}R}}{{{\rm d}r}}} \right) + {\dfrac{{G_1^G R}}{{\left( {r - r_c } \right)}} + \dfrac{{G_2^G R}}{{\left( {r - r_c^* } \right)}}} + G_3^G R = 0\,, \end{array} $
(56) where
$ \begin{array}{*{20}{l}} G_1^G = \dfrac{{\left( {\omega \left( {r_c^{2} + a^2 + n^2 } \right) - \left( {a\alpha - Q\beta r_c } \right)m' - \left( {a\gamma - Q\delta r_c } \right)q' } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}\,, \end{array} $
(57) $ \begin{array}{*{20}{l}} G_2^G = - \dfrac{{\left( {\omega \left( {r_c^{*2} + a^2 + n^2 } \right) - \left( {a\alpha - Q\beta r_c^* } \right)m' - \left( {a\gamma - Q\delta r_c^* } \right)q' } \right)^2 }}{{K^2 \left( {r_c - r_c^* } \right) }}, \end{array} $
(58) and
$ \begin{array}{*{20}{l}} G_3^G = \dfrac{{(\beta m' + \delta q')^2 Q^2 -\lambda }}{{K }}\,. \end{array} $
(59) In this general picture, the
$ J' $ -picture can be obtained by setting$ q' = 0 $ , and the$ Q' $ -picture is achieved at$ m'=0 $ . Note that these two$ J' $ and$ Q' $ pictures are equal to each other. In$ Q' $ -picture, the hidden conformal symmetry exists if we set the corresponding parameters in Eq. (40) to be$ \begin{array}{*{20}{l}} n_L^G = - \dfrac{{K\left( {2a\gamma - \delta Q\left( {r_c + r_c^* } \right)} \right)}}{{4\left( {a\gamma \left( {r_c + r_c^* } \right) + \delta Q\left( {a^2 + n^2 - r_c r_c^* } \right)} \right)}}\,, \end{array} $
(60) $ \begin{array}{*{20}{l}} n_R^G = \dfrac{{K\delta Q\left( {r_c - r_c^* } \right)}}{{4\left( {a\gamma \left( {r_c + r_c^* } \right) + \delta Q\left( {a^2 + n^2 - r_c r_c^* } \right)} \right)}}\,, \end{array} $
(61) $ \begin{array}{*{20}{l}} T_L^G = \dfrac{{K\left( {r_c^2 + \left( {r_c^* } \right)^2 + 2a^2 + 2n^2 } \right)}}{{4\pi \left( {a\gamma \left( {r_c + r_c^* } \right) + \delta Q\left( {a^2 + n^2 - r_c r_c^* } \right)} \right)}}\,, \end{array} $
(62) and
$ \begin{array}{*{20}{l}} T_R^G = \dfrac{{K\left( {r_c^2 - \left( {r_c^* } \right)^2 } \right)}}{{4\pi \left( {a\gamma \left( {r_c + r_c^* } \right) + \delta Q\left( {a^2 + n^2 - r_c r_c^* } \right)} \right)}}\,. \end{array} $
(63) -
In the previous section, we established the hidden conformal symmetries that are associated with the cosmological horizon in KNTNdS spacetime. These symmetries open the possibility to apply some CFT
$ _2 $ methods to understand several aspects related to the cosmological horizon. In this section, we show that the cosmological horizon entropy has a dual description from a CFT$ _2 $ point of view by using the Cardy formula. The same argument has been used to construct Kerr/CFT holography to recover the entropy of black holes [8, 10]. The dual calculations for the cosmological horizon entropy are performed separately in J and Q pictures, where each of them requires a particular approach to obtain the corresponding near horizon geometry.Let us first consider the J-picture. The appropriate near horizon coordinate transformation in the near extremal state is
$ \begin{aligned}[b] r = &\dfrac{{r_c + r_c^* }}{2} + \varepsilon r_0 \tilde r\, ,\quad r_c - r_c^* =& \mu \varepsilon r_0 \, , \\ t =& \tilde t\dfrac{{r_0}}{\varepsilon }\, , \quad \phi = \tilde \phi + \Omega _H \tilde t \dfrac{{r_0}}{\varepsilon }\,.\\ \end{aligned} $
(64) Applying this transformation to the metric (2) gives
$ \begin{aligned}[b] {\rm d}s^2 =& \Gamma \left( \theta \right)\left\{ { - {\left( {\tilde r - \dfrac{{\mu }}{2}} \right)\left( {\tilde r + \dfrac{{\mu }}{2}} \right) } {\rm d}\tilde t^2 + \dfrac{{{\rm d}\tilde r^2 }}{\left( {\tilde r - \dfrac{{\mu }}{2}} \right)\left( {\tilde r + \dfrac{{\mu }}{2}} \right)} + \alpha \left( x \right){\rm d}x^2 } \right\} \\ &+ \gamma \left( \theta \right)\left( {{\rm d}\tilde \phi + \tilde k^J {\tilde r} {\rm d}\tilde t} \right)^2 \,, \end{aligned} $
(65) where
$ \begin{array}{*{20}{l}} \Gamma \left( \theta \right) = \dfrac{{\rho _ c ^2 }}{{K}}\,, \end{array} $
(66) $ \begin{array}{*{20}{l}} \alpha \left( x \right) = \dfrac{{K }}{{\Delta _l \Delta_x }}\,, \end{array} $
(67) $ \begin{array}{*{20}{l}} \gamma \left( \theta \right) = \dfrac{{\Delta _l \Delta_x \left( {r_c^2 + a^2 + n^2 } \right)^2 }}{{\rho _c^2 }}\,, \end{array} $
(68) $ \begin{array}{*{20}{l}} \tilde k^J = \dfrac{{2 ar_c }}{{ \left( {r_ c ^2 + a^2 + n^2 } \right) K }}\,, \end{array} $
(69) and
$ \begin{array}{*{20}{l}} \rho _c^2 = r_c^2 + a^2 x^2 \,. \end{array} $
(70) A general formula to compute the central charge associated with the near horizon of a near extremal geometry in the family of Einstein-Maxwell theory has been computed in [9], and the obtained formula can apply to the near horizon geometry that appears in Eq. (65). The central charges are [9]
$ \begin{array}{*{20}{l}} c_L^J = c_R^J = 3\tilde k^J \displaystyle\int\nolimits_{-1}^1 {{\rm d}x \sqrt {\Gamma \left( x \right)\gamma \left( x \right)\alpha \left( x \right)} } \,, \end{array} $
(71) and for the cosmological horizon in the KNTNdS spacetime we have
$ \begin{array}{*{20}{l}} c_L^J = c_R^J = \dfrac{6a(r_c + r_c^*)}{K}\,. \end{array} $
(72) Using the central charge (72), the Cardy formula
$ \begin{array}{*{20}{l}} S_{\rm Cardy}^J = \dfrac{{\pi ^2 }}{3}\left( {c_L^J T_L^J + c_R^J T_R^J } \right) \end{array} $
(73) gives us the entropy of the cosmological horizon in KNTNdS spacetime, namely,
$ \begin{array}{*{20}{l}} S_{\rm Cardy}^J = {\pi \left( {r_c^2 + a^2 +n^2 } \right)}\,. \end{array} $
(74) In the next section, we will provide the holographic calculation for absorption cross section using a two point function of the operator that is dual to the scalar field. For that calculation, one needs to identify the conjugate charges
$ \delta E_L^J $ and$ \delta E_R^J $ that satisfy$ \begin{array}{*{20}{l}} \delta S_{\rm Cardy}^J = \dfrac{{\delta E_L^J }}{{T_L^J }} + \dfrac{{\delta E_R^J }}{{T_R^J }}\,. \end{array} $
(75) The conjugate charges can be obtained by using the first law of thermodynamics for the cosmological horizon (11), and the corresponding equation is
$ \begin{array}{*{20}{l}} \delta S = \dfrac{{\delta M - \Omega \delta J - \Phi \delta Q - \Psi dN - \Omega_n \delta J_n - \Theta \delta \Lambda }}{{T}} = \dfrac{{\delta E_L^J }}{{T_L^J }} + \dfrac{{\delta E_R^J }}{{T_R^J }}. \end{array} $
(76) Recall that for the Kerr-Newman black hole, the related first law of thermodynamics can be written as
$ \begin{array}{*{20}{l}} \delta M = T\delta S + \Omega \delta J + \Phi \delta Q\,. \end{array} $
(77) To obtain the conjugate charges in Kerr/CFT correspondence for the Kerr-Newman black hole, the variations of black hole parameters in Eq. (77) are related to some of the scalar probe parameters. The change in angular momentum is related to the magnetic quantum number m, whereas the change in electric charge is connected with the probe's electric charge.
However, the first law of thermodynamics (76) contains several terms that do not have a direct counterpart with the scalar probe's properties. Therefore, here we propose some generalizations for the variations related to the rotational and electromagnetic works, i.e.,
$ \begin{array}{*{20}{l}} \Omega ' \delta J' = \Omega \delta J + \Omega _n \delta J_n + \Theta \delta \Lambda \,. \end{array} $
(78) and
$ \begin{array}{*{20}{l}} \Phi ' \delta Q' = \Phi \delta Q + \Psi \delta N \,, \end{array} $
(79) respectively. In such generalizations, we can have
$ \delta M = \omega $ and$ \delta J' = m $ . In J-picture, we can have$ \begin{array}{*{20}{l}} \delta E_L^J = \omega _L^J \; \; {\rm and}\; \; \delta E_R^J = \omega _R^J \,, \end{array} $
(80) where
$ \begin{array}{*{20}{l}} \omega _L^J = \dfrac{{r_c^2 + \left( {r_c^* } \right)^2 + 2a^2 + 2n^2 }}{{2a }}\omega , \omega _R^J = \dfrac{{r_c^2 + \left( {r_c^* } \right)^2 + 2a^2 + 2n^2 }}{{2a }}\omega - m, \end{array} $
(81) $ \begin{array}{*{20}{l}} q_L^J = q_R^J=0\,,\; \; {\rm and}\; \; \mu_L^J = \mu_R^J = 0\,. \end{array} $
(82) Now let us turn to microscopic entropy calculation associated with the Q-picture hidden conformal symmetry. As it has been mentioned previously, we need to add a
$ U(1) $ internal extra dimension in the theory denoted by the coordinate χ. Then, the corresponding five dimensional spacetime metric can be read as$ \begin{array}{*{20}{l}} {\rm d}s^2 = {\rm d}s_4^2 + \left( {{\rm d}\chi + \tilde {\bf A}} \right)^2 \,, \end{array} $
(83) where
$ {\rm d}s_4^2 $ is the near horizon metric of the near extremal horizon (65) and$ \tilde {\bf A} $ is the associated gauge field. Now, let us consider the fluctuation of the five dimensional metric with a set of coordinates$\{ \tilde t,~\tilde \phi,~\theta,~\tilde r,~\chi \}$ in the following way,$ \begin{array}{*{20}{l}} h_{\mu \nu } \sim \left( {\begin{array}{*{20}c} {{\cal O}\left( {\tilde r^2 } \right)} & {{\cal O}\left( {\tilde r} \right)} & {{\cal O}\left( {1/\tilde r} \right)} & {{\cal O}\left( {1/\tilde r^2 } \right)} & {{\cal O}\left( 1 \right)} \\ {} & {{\cal O}\left( {1/\tilde r} \right)} & {{\cal O}\left( 1 \right)} & {{\cal O}\left( {1/\tilde r} \right)} & {{\cal O}\left( 1 \right)} \\ {} & {} & {{\cal O}\left( {1/\tilde r} \right)} & {{\cal O}\left( {1/\tilde r^2 } \right)} & {{\cal O}\left( {1/\tilde r} \right)} \\ {} & {} & {} & {{\cal O}\left( {1/\tilde r^3 } \right)} & {{\cal O}\left( {1/\tilde r} \right)} \\ {} & {} & {} & {} & {{\cal O}\left( 1 \right)} \\ \end{array}} \right)\,. \end{array} $
(84) The most general diffeomorphism that preserves the boundary condition in (84) is
$ \begin{array}{*{20}{l}} \zeta ^{\left( \chi \right)} = \varepsilon \left( \chi \right)\dfrac{\partial }{{\partial \chi }} - \tilde r\dfrac{{{\rm d}\varepsilon \left( \chi \right)}}{{{\rm d}\chi }}\dfrac{\partial }{{\partial \tilde r}}\,, \end{array} $
(85) where
$\varepsilon \left(\chi \right) = \exp \left(-{\rm i}q\chi\right)$ . To compute the central charge, we can generalize the treatment developed in [9] and we can obtain$ \begin{array}{*{20}{l}} c_L^Q = c_R^Q = 3 {\tilde k^Q} \displaystyle\int\nolimits_{-1}^{1} {{\rm d}x \sqrt {\Gamma \left( x \right)\gamma \left( x \right)\alpha \left( x \right)} } = \dfrac{6Q \left(r_c r_c^* -a^2 - n^2\right)}{K}\,. \end{array} $
(86) Note that the negative value of this central charge leads to the non-unitary CFT
$ _2 $ . Therefore, to guarantee the unitary, we have to impose$ r_c r_c^* > a^2 +n^2 $ and consider positive values of Q and K. However, sometimes the non-unitary dual CFT$ _2 $ is unavoidable in several systems. For example, in the case of a strong magnetic field for the magnetized Kerr/CFT holography [33]. This central charge can then be used to compute the microscopic entropy using the Cardy formula$ \begin{array}{*{20}{l}} S = \dfrac{{\pi ^2 }}{3}\left( {c_L^Q T_L^Q + c_R^Q T_R^Q } \right)\,, \end{array} $
(87) which recovers the entropy of the cosmological horizon in KNTNdS spacetime in Eq. (74).
Similar to the J-picture, the conjugate charges in Q-picture can be extracted from the first law of thermodynamics, i.e.,
$ \begin{array}{*{20}{l}} \delta S = \dfrac{{\delta M - \Omega' \delta J' - \Phi ' \delta Q' }}{{T }} = \dfrac{{\delta E_L^Q }}{{T_L^Q }} + \dfrac{{\delta E_R^Q }}{{T_R^Q }}\,, \end{array} $
(88) where
$ \Omega' \delta J' $ is given in (78) and$ \Phi ' \delta Q' $ is given in (79). However, given that in the Q-picture we only consider the case of$ m=0 $ , the term$ \Omega' \delta J' $ can be neglected. The last equation can be solved by setting$ \begin{array}{*{20}{l}} \delta E_L^Q = \omega _L^Q - q_L^Q \mu _L^Q \; \; ,\; \; \delta E_R^Q = \omega _R^Q - q_R^Q \mu _R^Q \,, \end{array} $
(89) where
$ \begin{array}{*{20}{l}} \omega _L^Q = \omega _R^Q = \dfrac{{n\left( {r_c + r_c^* } \right)\left( {r_c^2 + \left( {r_c^* } \right)^2 + 2a^2 + 2n^2} \right)}}{{2Q\left( {r_c r_c^* - a^2 - n^2} \right)}}\omega \,, \end{array} $
(90) $ \begin{array}{*{20}{l}} q_L^Q = q_R^Q = \delta Q_c = q\,, \end{array} $
(91) and
$ \begin{array}{*{20}{l}} \mu _L^Q = \dfrac{{n\left( {r_c^2 + \left( {r_c^* } \right)^2 + 2a^2+2n^2 } \right)}}{{2\left( {r_c r_c^* - a^2 -n^2 } \right)}}\; \; ,\; \; \mu _R^Q = \dfrac{{n\left( {r_c + r_c^* } \right)^2 }}{{2\left( {r_c r_c^* - a^2-n^2 } \right)}}\,. \end{array} $
(92) Before proceeding to the next section, let us discuss here the results above. As we have mentioned in the introduction, a holography for de Sitter geometry has been reported in [15], where the author established a connection between the gravity theory in the D-dimensional de Sitter space with a conformal field theory living in a (D-1)-sphere. Particularly, for the three dimensional de Sitter (dS
$ _3 $ ) background, the corresponding dual theory is a two dimensional conformal field theory that is exactly the case presented in this paper. Moreover, the technique to compute the central charge that is associates with the asymptotics symmetries of dS$ _3 $ is the analogous calculation presented by Brown and Henneaux in [34]. In fact, the method of Brown and Henneaux for the central charge is also the method adopted in Kerr/CFT correspondence [8]. As we have mentioned previously, the work presented in this paper is an application of Kerr/CFT correspondence to the cosmological horizon of the KNTNdS spacetime. Therefore, one can say that basically the work in this paper and the dS/CFT correspondence reported in [15] depart from the same basis. Note that the author of [15] is also one of the authors of [8] and [31], where the Kerr/CFT correspondence was established.However, the constructions of dS/CFT holography in [15] and the one presented here differ in several aspects. First, the dual CFT theory proposed in [15] is (D-1)-dimensional, with D as the dimension of the gravitational theory in dS
$ _3 $ . Typically in the Kerr/CFT holography, the dual CFT theory is two dimensional regardless of the dimension of the bulk spacetime under consideration [10, 15]. Second, the asymptotic geometry considered in [15] is still de Sitter, whereas in this paper the corresponding near-horizon of (near)-extremal geometry that appeared in Eq. (65) is warped anti-de Sitter. Consequently, these different asymptotic geometries require different types of boundary conditions to be used in the diffeomorphism generators that lead to distinctive central charges. Third, the central charge obtained in this work fails to reduce smoothly to the non-rotating or neutral cases. It can be observed that in general the central charges (72) and (86) vanish in the case of$ a=0 $ and$ Q=0 $ , respectively. This limitation is well known for the Kerr/CFT correspondence as it works for the rotating and/or charged case only, i.e., the black hole/CFT correspondence for Schwarzschild black hole in the style of [8] is not well established. Further, the holography for de Sitter spacetime established in [15] can be extended to the case that incorporates black holes [35]. -
Normally, in the discussions of Kerr/CFT correspondence for black holes, another evidence that supports the holography is the dual calculation for scalar absorption near the horizon. Similar to that, here we also provide such calculations in the near cosmological horizon, and show that the dictionary of Kerr/CFT correspondence still applies. To start, let us consider the frequency near the superradiant bound for the scalar field,
$ \begin{array}{*{20}{l}} \omega - m\Omega - q \Phi = {\bar \omega} \dfrac{\varepsilon}{r_0}\,. \end{array} $
(93) The scattering analysis can be conducted in the J- or Q-picture, and consequently it should be feasible in the general picture as well. Here let us consider the J-picture only, where the corresponding radial equation is Eq. (41). The solution to this equation reads
$ \begin{array}{*{20}{l}} R\left( \zeta \right) = \zeta^\alpha \left( {1 - \zeta} \right)^\beta F\left( {a,b,c;\zeta} \right)\,, \end{array} $
(94) where
$ \zeta = \left({r - r_c } \right)\left({r - r_c^* } \right)^{ - 1} $ ,$ \begin{array}{*{20}{l}} {\rm i}\alpha = \sqrt {G_1^J } \,, \end{array} $
(95) $ \begin{array}{*{20}{l}} 2 \beta = 1 - \sqrt {1 - 4 G_3^J } \,, \end{array} $
(96) and
$ \begin{array}{*{20}{l}} a^{*} = \alpha + \beta + {\rm i}\sqrt { - G_2^J }\; \; ,\; \; b^{*} = \alpha + \beta - {\rm i}\sqrt { - G_2^J } \; \; ,\; \; c^{*} = 1 + 2\alpha \,. \end{array} $
(97) Moreover, the radial solution (94) in the near horizon of the near extremal setup can be read as
$ \begin{array}{*{20}{l}} R\left( {\bar \zeta} \right) = {\bar \zeta}^{\bar \alpha } \left( {1 - {\bar \zeta}} \right)^{\bar \beta } F\left( {\bar a^* ,\bar b^* ,\bar c^* ;{\bar \zeta}} \right)\,, \end{array} $
(98) where
$ \begin{array}{*{20}{l}} {\bar \zeta} = \dfrac{\left( {\tilde r - \mu /2} \right)}{\left( {\tilde r + \mu /2} \right)}\,, \end{array} $
(99) and the incorporating parameters are
$ \begin{array}{*{20}{l}} {\rm i}\bar \alpha = \sqrt {\bar G_1^J } \,, \end{array} $
(100) $ \begin{array}{*{20}{l}} 2\bar \beta = 1 - \sqrt {1 - 4\bar G_3^J } \,, \end{array} $
(101) $ \begin{array}{*{20}{l}} \bar a^* = \bar \alpha + \bar \beta + {\rm i}\sqrt { - \bar G_2^J } \; \; ,\; \; \bar b^* = \bar \alpha + \bar \beta - {\rm i}\sqrt { - \bar G_2^J }\; \; ,\; \; \bar c^* = 1 + 2\bar \alpha \,, \end{array} $
(102) and
$ \begin{array}{*{20}{l}} \bar G_1^J = \dfrac{{\left( {\bar \omega } \right)^2 }}{{\bar \lambda ^2 }}\; \; ,\; \; \bar G_2^J = - \left( {\dfrac{{\bar \omega }}{{\bar \lambda }} - \dfrac{{2r_c m\Omega _c }}{K}} \right)^2 \; \; ,\; \; \bar G_3^J = - \dfrac{{\bar\lambda}}{K}\,. \end{array} $
(103) Now, let us consider the asymptotics of the radial solution (98) above. If one takes
$ \bar\zeta \gg \mu $ , which corresponds to a large$ \tilde r $ , the radial solution above reduces to$ \begin{array}{*{20}{l}} R(\bar\zeta) \sim C_ + {\bar\zeta}^{h - 1} + C_ - {\bar\zeta}^{ - h} \,. \end{array} $
(104) In such asymptotics, one can get the corresponding retarded Green function in the form
$ \begin{array}{*{20}{l}} G_R \sim \dfrac{{C_ - }}{{C_ + }}\,. \end{array} $
(105) Explicitly, in our near horizon of the near extremal setup, the reading of this retarded Green function is
$ \begin{array}{*{20}{l}} G_R \sim \dfrac{{\Gamma \left( {1 - 2h} \right)}}{{\Gamma \left( {2h - 1} \right)}}\dfrac{{\Gamma \left( {h - {\rm i}\left( {{\bar G}_1^J - {\bar G}_2^J } \right)} \right)\Gamma \left( {h - {\rm i}\left( {{\bar G}_1^J + {\bar G}_2^J } \right)} \right)}}{{\Gamma \left( {1 - h - {\rm i}\left( {{\bar G}_1^J - {\bar G}_2^J } \right)} \right)\Gamma \left( {1 - h - {\rm i}\left( {{\bar G}_1^J + {\bar G}_2^J } \right)} \right)}}\,. \end{array} $
(106) Interestingly, the Green function above has an agreement with a two point function of the scalar operator in a CFT
$ _2 $ . For a scalar operator$ \hat O $ that is dual to the scalar test probe, the two point function can be written as$ \begin{array}{*{20}{l}} G\left( {{\tau} ^ + ,{\tau} ^ - } \right) = \langle {\hat O^\dagger \left( {{\tau} ^ + ,{\tau} ^ - } \right),\hat O\left( {0,0} \right)} \rangle \,, \end{array} $
(107) where the left and right moving coordinates in a two dimensional worldsheet are given by
$ {\tau} ^ + $ and$ {\tau} ^ - $ , respectively. The two point function (107) is dictated by the conformal invariance and can be read as [32, 29]$ \begin{aligned}[b] &G\left( {{\tau} ^ + ,{\tau} ^ - } \right) \sim \left( { - 1} \right)^{h_L + h_R } \left( {\dfrac{{\pi T_L^J }}{{\sinh \left( {\pi T_L^J {\tau} ^ + } \right)}}} \right)^{2h_L } \left( {\dfrac{{\pi T_R^J }}{{\sinh \left( {\pi T_R^J {\tau} ^ - } \right)}}} \right)^{2h_R } \\ &{\rm e}^{{\rm i}\left( {q_L^J \mu _L^J {\tau} ^ + + q_R^J \mu _R^J {\tau} ^ - } \right)} \,, \end{aligned} $
(108) where
$\left(h_L,~h_R\right)$ are the conformal dimensions, and$ h_L = h_R =h $ . It is understood that$\left(q_L^J,~q_R^J\right)$ are the charges,$\left(T_L^J,~T_R^J\right)$ are the temperatures, and$\left(\mu_L^J,~\mu_R^J \right)$ are the chemical potentials associated with the operator$ \hat O $ . In the equation above, we have incorporated the parameters in the J-picture. The Euclidean correlator can be evaluated along the positive imaginary$\left\{\omega_{L}^J,~\omega_{R}^J\right\}$ axis, i.e.,$ \begin{array}{*{20}{l}} G_E \left( {\omega _{L,E}^J ,\omega _{L,E}^J } \right) = G_R \left( {{\rm i}\omega _{L,E}^J ,{\rm i}\omega _{L,E}^J } \right)\,, \end{array} $
(109) for a positive
$ \left\{\omega _{L,E}^J,\omega _{L,E}^J\right\} $ . In the theory with a finite temperature,$ \omega _{L,E}^J $ and$ \omega _{L,E}^J $ are discrete and take the values of Matsubara frequencies,$ \begin{array}{*{20}{l}} \dfrac{{\omega _{L,E}^J }}{{2\pi T_L^J }} = m_L \; \; {\rm and}\; \; \dfrac{{\omega _{R,E} }}{{2\pi T_R^J }} = m_R \,, \end{array} $
(110) where
$ m_L $ and$ m_R $ are integers.A Wick rotation is performed to the 2D worldsheet coordinate, i.e.,
$ \begin{array}{*{20}{l}} \tau^ + \to {\rm i}\tau _L \; \; {\rm and}\; \; \tau^ - \to {\rm i}\tau _R \,, \end{array} $
(111) where the Euclidean time
$ \tau_L $ and$ \tau_R $ have the periodicity$ 2\pi/T_L^J $ and$ 2\pi/T_R^J $ , respectively. Accordingly, the Euclidean correlator obtained from the two point function (107) can be written as$ \begin{aligned}[b] &G_E \left( {\omega _{L,E}^J ,\omega _{R,E}^J } \right) \sim {T_L^J}^{2h_L - 1} {T_R^J}^{2h_R - 1} \\ &\exp \left[ {{\rm i}\left( {\dfrac{{\tilde \omega _{L,E}^J }}{{2T_L^J }} + \dfrac{{\tilde \omega _{R,E} }}{{2T_R^J }}} \right)} \right]\Gamma \left( {h_L + \dfrac{{\tilde \omega _{L,E}^J }}{{2\pi T_L^J }}} \right)\Gamma \left( {h_L - \dfrac{{\tilde \omega _{L,E}^J }}{{2\pi T_L^J }}} \right) \\ &\times \Gamma \left( {h_R + \dfrac{{\tilde \omega _{R,E} }}{{2\pi T_R^J }}} \right)\Gamma \left( {h_R - \dfrac{{\tilde \omega _{R,E} }}{{2\pi T_R^J }}} \right)\,, \end{aligned} $
(112) where
$ \begin{array}{*{20}{l}} \tilde \omega _{L,E}^J = \omega _{L,E}^J - {\rm i}q_L^J \mu _L^J \; \; {\rm and}\; \; \tilde \omega _{R,E}^J = \omega _{R,E}^J - {\rm i}q_R^J \mu _R^J \,. \end{array} $
(113) The agreement between (112) and (106) establishes the correspondence between a two dimensional conformal field theory and the cosmological horizon in terms of scalar absorption calculation. It can be viewed as another supporting evidence for the Kerr/CFT correspondence of the cosmological horizon.
-
It has been shown that there exists a strong correlation between the existence of non-extremal Kerr/CFT correspondence and the pair production known as Schwinger effect near the horizon at the near extremal state [19, 20]. In the previous sections, we have shown that the Kerr/CFT holography dictionary can also be applied to the cosmological horizon. This motivates us to investigate the possibility for the Schwinger effect to take place near the KNTNdS cosmological horizon. However, the required near horizon transformation is slightly different compared to the one in Eq. (64) when we compute the central charge. The appropriate one to show the Schwinger effect is
$ \begin{aligned}[b] & r \to {\tilde r}_0 + \varepsilon \hat r \; ,\; {\rm d}t \to \dfrac{{\left( {{\tilde r}_0^2 + a^2 + n^2 } \right)}}{{\Delta _0 \varepsilon }}{\rm d}\hat t \; , \\ &{\rm d}\phi \to {\rm d}\hat \phi + \dfrac{{\hat \Omega \left( {{\tilde r}_0^2 + a^2 + n^2 } \right)}}{{\Delta _0 \varepsilon }}{\rm d}\hat t\,. \end{aligned} $
(114) Note that we use the "hat" notation for the near horizon coordinate to distinguish it with the "tilde" one in (65). In addition to the coordinate changes above, the mass is also shifted as
$ \begin{array}{*{20}{l}} M \to M_0 + \dfrac{{\Delta _0 B^2 }}{{2{\tilde r}_0 }}\varepsilon ^2 \,. \end{array} $
(115) Applying the transformations above to the spacetime metric (2) and the vector solution (5) followed by taking
$ \varepsilon \to 0 $ yields$ \begin{aligned}[b] {\rm d}s^2 =& - \dfrac{{\rho _0^2 }}{{\Delta _0 }}\left( {{\hat r}^2 - B^2 } \right){\rm d}\hat t^2 + \dfrac{{\rho _0^2 }}{{\Delta _0 \left( {{\hat r}^2 - B^2 } \right)}}{\rm d}\hat r^2 + \dfrac{{\rho _0^2 }}{{\Delta _l \Delta _x }}{\rm d}x^2 \\ &+ \dfrac{{Z^2 \Delta _l \Delta _x }}{{\rho _0^2 }}\left( {{\rm d}\hat \phi + \dfrac{{2a{\tilde r}_0 \hat r}}{{Z\Delta _0 }}{\rm d}\hat t} \right) \end{aligned} $
(116) where
$ Z={\tilde r}_0^2 + a^2 + n^2 $ ,$ \begin{array}{*{20}{l}} \Delta _0 = 1 - \dfrac{{a^2 + 6\left( {{\tilde r}_0^2 + n^2 } \right)}}{{l^2 }} \,, \end{array} $
(117) $ \begin{array}{*{20}{l}} \rho_0^2 = {\tilde r}_0^2 + (n+ax)^2 \,, \end{array} $
(118) and the corresponding gauge field is
$ \begin{array}{*{20}{l}} A_\mu {\rm d}x^\mu = - \dfrac{{Q\left( {{\tilde r}_0^2 - \left( {n + ax} \right)^2 } \right)\hat r}}{{\rho _0^2 \Delta _0 }}{\rm d}\hat t - \dfrac{{Q{\tilde r}_0 Z}}{{a\rho _0^2 }}{\rm d}\hat \phi\,. \end{array} $
(119) Interestingly, the result for the near horizon geometry (116) looks similar to the near horizon metric (65) that gives the central charge (72). However, a closer look will show that these near horizon metrics are actually different from one another. This is understandable because the associated coordinate transformations to produce these near horizon metrics are slightly different. The coordinate transformation (64) incorporates the variables
$ r_c^* $ and K, which are basically the outcome of approaching$ \Delta_r $ in the KNTNdS metric (2) to be quadratic in r. Recall that such quadratic property is required to reveal the hidden conformal symmetry of the scalar probe. Accordingly, the associated central charge for the near horizon geometry (65) is the one needed to produce the Cardy entropy (74) after employing the left and right movers temperatures in the related hidden conformal symmetry generators. Meanwhile, the near horizon geometry (116) and the corresponding coordinate transformation (114) do not incorporate$ r_c^* $ and K, as we consider the KNTNdS line element without any approximation for the$ \Delta_r $ function. However, suppose that the central charge that corresponds to the asymptotic symmetry of the near horizon geometry (116) is computed. The resulting entropy after using the Cardy formula and the suitable temperatures obtained in Sec. III will not match the expected entropy for the KNTNdS cosmological horizon. Nevertheless, for the case without cosmological constant, the near horizon of extremal black holes obtained by using the coordinate transformation (114) can give the appropriate central charge to reproduce the related Bekenstein-Hawking entropy. For example, using the general central charge formula (71) for the near horizon of the extremal Kerr-Newman black hole in [36] gives the correct central charge$ c=12 Ma $ for the microscopic entropy calculation in J-picture [28]. Note that Ref. [36] discusses the Schwinger effect near the Kerr-Newman black hole.Now let us consider the Klein-Gordon equation for a charged massive test scalar in the near horizon of the near extremal geometry constructed above. The general form reads
$ \begin{array}{*{20}{l}} \left( {\nabla _\mu + {\rm i}qA_\mu } \right)\left( {\nabla ^\mu + {\rm i}qA^\mu } \right)\Psi = \mu^2 \Psi \,, \end{array} $
(120) where μ is mass for the scalar field. To proceed, we employ a similar ansatz as the one we used to show the hidden conformal symmetry in Sec. III. In the appropriate coordinate, it reads
$ \begin{array}{*{20}{l}} \hat \Phi = \exp \left( { - {\rm i}\hat \omega \hat t + {\rm i}\hat m\hat \phi } \right)X\left( x \right)\hat R\left( {\hat r} \right) \,. \end{array} $
(121) Subsequently, the resulting equations are
$ \begin{aligned}[b] &\Delta _0 \partial _{\hat r} \left\{ {\left( {\hat r^2 - B^2 } \right)\partial _{\hat r} \hat R\left( {\hat r} \right)} \right\} +\\ &\left\{ {\dfrac{{\left( {Z\Delta _0 \hat \omega - qQZ\hat r + 2{\tilde r}_0 a\hat m\hat r} \right)^2 }}{{Z^2 \Delta _0 \left( {\hat r^2 - B^2 } \right)}} - \mu ^2 Z - \lambda _l } \right\}R = 0 \,, \end{aligned} $
(122) and
$ \begin{aligned}[b] &\partial _x \left\{ {\Delta _l \Delta _x X\left( x \right)} \right\} -\\ &\left\{ {\dfrac{{\left( {qQ{\tilde r}_0 Z - a\rho _0^2 \hat m} \right)^2 }}{{a^2 \Delta _x Z^2 \Delta _l }} - \mu ^2 \left( {a\Delta _x - 2nx} \right) - \lambda _l } \right\}X\left( x \right) = 0\,. \end{aligned} $
(123) Accordingly, the effective mass in the radial Eq. (122) can be written as [19–21]
$ \begin{array}{*{20}{l}} m_{\rm eff}^2 = m^2 - \dfrac{{\left( {2{\tilde r}_0 a\hat m - qQZ} \right)^2 }}{{Z^3 \Delta _0 }} + \dfrac{{\lambda _l }}{Z}\,. \end{array} $
(124) The corresponding Breitenlohner-Freedman bound that associates to the stability condition in the near horizon of AdS space, i.e.,
$m_{\rm eff}^2 \geqslant \dfrac{1}{4}L_{\rm AdS}^{-2}$ , can be expressed as$ \begin{array}{*{20}{l}} m_{{\rm{eff}}}^2 \geqslant - \dfrac{{\Delta _0 }}{{4Z}}\,. \end{array} $
(125) The violation of the Breitenlohner-Freedman bound as stated in (125) leads to the Schwinger effect near the cosmological horizon in the KNTNdS spacetime. Similar to the pair production from the black hole horizon in the near extremal state, such an effect can also take place near the cosmological horizon. Indeed, the horizon must be in the near extremal condition, so it has the warped AdS structure that is needed in the prescription to show the Schwinger effect [19, 20].
We do not present here the thermal interpretation for the Schwinger effect above. However, this can be done straightforwardly by following the prescription given in [19, 21]. Illustrations for the Breitenlohner-Freedman bound violation are given in Fig. 4 where the corresponding
$ {\tilde r}_0 $ values are evaluated in Fig. 5. Note that we require$ {\tilde r}_0 $ to be real so the corresponding plots in Fig. 4 are well defined. The plots in Fig. 4 confirm that the pair production can exist, and we can observe how the NUT parameter affects the magnitude of$\Upsilon =m_{{\rm{eff}}}^2 + \dfrac{{\Delta _0 }}{{4Z}} < 0$ . Thus, we can infer that the presence of the NUT parameter yields the stronger violation of the Breitenlohner-Freedman bound.Figure 5. Values of
$ {\tilde r}_0 $ that correspond to the plots in Fig. 4.
Hidden conformal symmetry and pair production near the cosmological horizon in Kerr-Newman-Taub-NUT-de Sitter spacetime
- Received Date: 2022-10-26
- Available Online: 2023-03-15
Abstract: We show that the study of the hidden conformal symmetry that is associated with the Kerr/CFT correspondence can also apply to the cosmological horizon in the Kerr-Newman-Taub-NUT-de Sitter spacetime. This symmetry allows employing some two dimensional conformal field theory methods to understand the properties of the cosmological horizon. The entropy can be understood by using the Cardy formula, and the equation for the scattering process in the near region is in agreement with that obtained from a two point function in the two-dimensional conformal field theory. We also show that pair production can occur near the cosmological horizon in Kerr-Newman-Taub-NUT-de Sitter for near extremal conditions.