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The Einstein-Maxwell-Dilaton action in
$ (n+1) $ -dimensional spacetime reads [8]$ \begin{aligned}[b] S =& \frac{1}{16\pi}\int {\rm d}^{n+1}x \sqrt{-g}\Bigg(\mathcal{R}-\frac{4}{n-1}(\nabla \Phi)^2-V(\Phi)\\&-{\rm e}^{-4\alpha \Phi/(n-1)}F_{\mu\nu}F^{\mu\nu}\Bigg), \end{aligned} $
(1) where
$ \mathcal{R} $ ,$ \Phi $ , and$ F_{\mu\nu} $ denote the Ricci scalar curvature, dilaton field, and electromagnetic field tensor, respectively. The parameter$ \alpha $ describes the strength of the coupling between the electromagnetic and dilaton fields.To obtain a solution, one must adopt a specific form of the potential of the dilaton field
$ V(\Phi) $ ; in this case,$ V(\Phi) = $ $ 2\Lambda_0{\rm e}^{2\zeta_0\Phi}+2\Lambda {\rm e}^{2\zeta\Phi} $ [8, 17, 18, 26]. Note that if the power-law Maxwell field is considered [22], an additional term should be added to the above potential.One can take the general form of the metric as [26]
$ {\rm d}s^2 = -f(r){\rm d}t^2+\frac{1}{f(r)}{\rm d}r^2+r^2R^2(r)h_{ij}{\rm d}x^i{\rm d}x^j, $
(2) where
$ h_{ij}{\rm d}x^i{\rm d}x^j $ corresponds to an$ (n-1) $ -dimensional hypersurface with constant scalar curvature$ (n-1)(n-2)k $ , where k can be taken as$ -1,\;0,\;1 $ , corresponding to hyperbolic, flat, and spherical constant curvature hypersurfaces, respectively.Employing the ansatz
$ R = {\rm e}^{2\alpha\Phi/(n-1)} $ , the solution can be derived [26] as$ \begin{aligned}[b] f(r) =& -\frac{k(n-2)(1+\alpha^2)^2b^{-2\gamma}r^{2\gamma}}{(\alpha^2-1)(\alpha^2+n-2)}-\frac{m}{r^{(n-1)(1-\gamma)-1}}\\&+\frac{2\Lambda b^{2\gamma}(1+\alpha^2)^2r^{2(1-\gamma)}}{(n-1)(\alpha^2-n)} \\& +\frac{2q^2(1+\alpha^2)^2b^{-2(n-2)\gamma}r^{2(n-2)(\gamma-1)}}{(n-1)(n+\alpha^2-2)},\end{aligned}$
(3) $ \Phi(r) = \frac{(n-1)\alpha}{2(\alpha^2+1)}\ln \left(\frac{b}{r}\right), $
(4) where b is an arbitrary constant and
$ \gamma $ is related to$ \alpha $ by$ \gamma = \alpha^2/(\alpha^2+1) $ . The coefficients in the expression of$ V(\Phi) $ are [26]$ \Lambda_0 = \frac{k(n-1)(n-2)\alpha^2}{2b^2(\alpha^2-1)},\;\;\;\zeta_0 = \frac{2}{\alpha(n-1)},\;\;\;\;\zeta = \frac{2\alpha}{n-1}.$
(5) The mass, charge, Hawking temperature, and entropy are obtained as [26, 27]
$ M = \frac{b^{(n-1)\gamma}(n-1)\omega_{n-1}m}{16\pi (\alpha^2+1)} , $
(6) $ Q = \frac{\omega_{n-1}q}{4\pi}, $
(7) $\begin{aligned}[b] T=& \frac{-(1+\alpha^2)}{2\pi(n-1)}\Bigg[\frac{k(n-2)(n-1)}{2b^{2\gamma}(\alpha^2-1)}r_+^{2\gamma-1}+\Lambda b^{2\gamma} r_+^{1-2\gamma}\\&+q^{2}b^{-2(n-2)\gamma}r_+^{(2n-3)(\gamma-1)-\gamma}\Bigg], \end{aligned} $
(8) $ S = \frac{\omega_{n-1}b^{(n-1)\gamma}r_+^{(n-1)(1-\gamma)}}{4}. $
(9) where the parameter
$ m $ can be derived via$ f(r_+) = 0 $ .By considering the conditions that the electric potential
$ A_t $ should be finite at infinity and the parameter m should vanish at spacial infinity, the restrictions on$ \alpha $ for dilaton black holes coupled with the power-law Maxwell field were obtained [22] as$ 0\leqslant\alpha^2<n-2 $ for the case where$ \dfrac{1}{2}<p<\dfrac{n}{2} $ , and as$ 2p-n<\alpha^2<n-2 $ for the case where$ \dfrac{n}{2}<p<n-1 $ , where p describes the nonlinearity of the electromagnetic field. For the Maxwell field considered here,$ p = 1 $ , reducing the corresponding restriction to$ 0\leqslant\alpha^2<n-2 $ . -
To investigate the dynamic phase transition of charged dilaton black holes, we introduce the “Gibbs free energy landscape” and define the corresponding Gibbs free energy
$ G_{\rm L} $ as$ G_{\rm L} = H-T_{\rm E}S $ . Here,$ T_{\rm E} $ denotes the temperature of the ensemble. Via Eqs. (6) and (9),$ G_{\rm L} $ of the dilaton black hole is calculated as$ \begin{aligned}[b]G_{\rm L} =& \frac{\omega_{n-1}b^{(n-1)\gamma}r_+^{n-2+(1-n)\gamma}}{16\pi}\Bigg\{\Bigg[\frac{2b^{-2(n-2)\gamma} q^2r_+^{2(n-2)(\gamma-1)}}{(n-1)(\alpha^2+n-2)}\\&-\frac{k(n-2)b^{-2\gamma}r_+^{2\gamma}}{(\alpha^2-1)(\alpha^2+n-2)}+\frac{16\pi P b^{2\gamma}r_+^{2(1-\gamma)}}{(n-1)(n-\alpha^2)}\Bigg] \\& \times(n-1)(1+\alpha^2)-4\pi r_+T_{\rm E}\Bigg\}, \end{aligned} $
(10) where we have introduced the extended phase space and set the thermodynamic pressure as
$ P = -\Lambda/8\pi $ .To observe the behavior of
$ G_{\rm L} $ $ G_{\rm L} $ it is plotted for various temperatures in Figs. 1(b)-1(f). We chose five characteristic temperatures, namely,$ T_1 $ ,$ T_2 $ ,$ T_3 $ ,$ T_4 $ , and$ T_5 $ . From Fig.1(a), we observe that$ T_1 $ and$ T_5 $ each correspond to a single phase,$ T_2 $ and$ T_4 $ correspond to three phases, and$ T_3 $ corresponds to two phases (one being a coexistent phase). All phases are denoted by black dots in Fig. 1. When$ T_{\rm E} = T_1 $ and$ T_{\rm E} = T_5 $ , there is only one local minimum (forming one well in the curve). For$ T_{\rm E} = T_2 $ and$ T_{\rm E} = T_4 $ , there are two local minimums and one local maximum (leading to two wells of different depths). For the case of$ T_{\rm E} = T_3 $ , there are two local minimum points (denoting the stable black hole phases) and one local maximum point (denoting the unstable black hole phase), that is, there are two wells also in the curve. However, in contrast to the$ T_{\rm E} = T_2 $ and$ T_{\rm E} = T_4 $ cases, these wells have the same depth. Therefore, Fig. 1(d) represents the phase transition between the small black hole and large black hole.Figure 1. (color online)
$ \alpha = 0.2 $ and$ P = 0.003 $ . (a)$ G-T $ , (b)$ G-r_{+} $ for$ T_{1} = 0.0444 $ , (c)$ G-r_{+} $ for$ T_{2} = 0.0451 $ , (d)$ G-r_{+} $ for$ T_{3} = 0.0453 $ , (e)$ G-r_{+} $ for$ T_{4} = 0.0456 $ , and (f)$ G-r_{+} $ for$ T_{5} = 0.0466 $ .Based on
$ G_{\rm L} $ , we can utilize the following Fokker-Planck equation [64-68] to investigate the probabilistic evolution of the black hole after the thermal fluctuation,$ \frac{\partial \rho(r,t)}{\partial t} = D\frac{\partial}{\partial r}\left\{{\rm e}^{-\beta G_{\rm L}(T,P,r)}\frac{\partial}{\partial r}\left[{\rm e}^{\beta G_{\rm L}(T,P,r)}\rho(r,t)\right]\right\}, $
(11) where
$ \rho(r,t) $ denotes the probability distribution. Additionally, the parameter$ \beta = \dfrac{1}{k_{\rm B} T} $ incorporates$ k_{\rm B} $ as the Boltzman constant, and the diffusion coefficient$ D = \dfrac{k_{\rm B} T}{\zeta} $ incorporates$ \zeta $ , which denotes the dissipation coefficient. Without loss of generality,$ \zeta $ and$ k_{\rm B} $ can be set to one. For conciseness, we employ r to replace the notation$ r_+ $ for the black hole horizon radius here and hereafter.Before solving the above equation, the boundary condition and the initial condition must first be imposed. The initial condition can be chosen as a Gaussian wave packet located at the small and large dilaton black hole states, respectively. Namely,
$ \rho(r,0) = \dfrac{1}{\sqrt{\pi}a}{\rm e}^{-(r-r_{{\rm l(s)}})^2/a^2} $ , with$ r_{\rm l} $ and$ r_{\rm s} $ denoting the horizon radius of the large and small dilaton black holes, respectively, and a denoting the width of Gaussian wave packet. In this study, we set$ a = 0.1 $ .There are several types of boundary conditions, such as the reflecting boundary condition, absorbing boundary condition, and periodic boundary condition. Here, as
$ G_{\rm L} $ is not periodic, the periodic boundary condition is not considered. To investigate the dynamic phase transition of black holes, we consider the reflecting boundary condition and the absorbing boundary condition. The former condition can ensure the normalization of$ \rho $ . This can be considered as$ \beta G'(r)\rho(r,t)+\rho'(r,t)\big|_{r = r_0} = 0 $ , while the absorbing boundary condition can be considered as$ \rho(r_m,t) = 0 $ (the meaning of$ r_m $ is discussed in the next paragraph).We numerically solve Eq. (11), constrained by both the initial condition and the reflecting boundary condition. Fig. 2 shows the time evolution of the probability distribution
$ \rho(r,t) $ of charged dilaton AdS black holes, where the thermodynamic pressure was chosen as$ P = 0.003 $ . For the top, middle, and bottom rows of Fig. 2, the values of parameter$ \alpha $ , which characterizes the strength of coupling between the electromagnetic field and the dilaton field, were chosen as 0.4, 0.2, and 0, respectively, to compare the effect of dilaton gravity on the probability evolution.Figure 2. (color online) Time evolution of
$ \rho(r,t) $ for charged dilaton black hole with$ b = 1, \;q = 1, \;P = 0.003 $ . (a)$ \alpha = 0.4 $ , (b)$ \alpha = 0.4 $ (c)$ \alpha = 0.2$ , (d)$ \alpha = 0.2 $ (e)$ \alpha = 0$ , and (f)$ \alpha = 0 $ . For (a), (c), and (e), the initial condition was chosen as a Gaussian wave packet located at the large dilaton black hole state, while for (b), (d), and (f), the initial condition was chosen as a Gaussian wave packet located at the small dilaton black hole state.For Figs. 2(a), (c), and (e), the initial condition was chosen as a Gaussian wave packet located at the large dilaton black hole state. This is reflected in the graphs, as the initial peak of
$ \rho(r,t) $ corresponds to the radius of the large dilaton black hole. With time evolution, the initial peak decreases, while the peak corresponding to the radius of the small dilaton black hole increases. Eventually, these two peaks reach a stationary distribution in which they appear equal to each other. This demonstrates the dynamic process of the large dilaton black hole evolving into the small dilaton black hole. Therefore, the left three graphs correspond to the case where the large dilaton black hole evolves dynamically into the small dilaton black hole.In contrast, the initial condition for Figs. 2(b), (d), and (f) was chosen as a Gaussian wave packet located at the small dilaton black hole state. The initial peak located at the small dilaton black hole decays over time, while the peak corresponding to the radius of the large dilaton black hole grows. Eventually, these two peaks approach a stationary distribution. Therefore, the right three graphs of Fig. 2 correspond to the case where the small dilaton black hole evolves dynamically into the large dilaton black hole.
The effect of dilaton gravity can be observed by comparing the top two graphs (
$ \alpha = 0.4 $ ) to the middle two graphs ($ \alpha = 0.2 $ ) and the bottom two graphs ($ \alpha = 0 $ ) in Fig. 2. Firstly, the difference in horizon radius between the large and small dilaton black holes increases with the parameter$ \alpha $ . Secondly, with increasing$ \alpha $ , the system requires more time to reach a stationary distribution. Finally, the greater the overlap of the two waves, the lesser the amount of time taken for the phase transition, as it is much easier for the phase transition to take place if the two phases are more similar.Figure 3 provides a complementary, more quantitative picture of the time evolution of
$ \rho(r_{\rm l},t) $ and$ \rho(r_{\rm s},t) $ . The effect of the dilaton gravity is quite obvious. It is observed that for a larger$ \alpha $ , the phase transition is more gradual. This can be explained by the analysis in Table 1; the larger the value of$ \alpha $ , the deeper the well of Gibbs free energy. Moreover, the final values of$ \rho(r_{\rm l},t) $ and$ \rho(r_{\rm s},t) $ vary with$ \alpha $ . The values can be read from the graph, with 0.229 for$ \alpha = 0.4 $ , 0.250 for$ \alpha = 0.2 $ , and 0.297 for$ \alpha = 0 $ . This difference can be viewed as the third effect (in addition to the two observations mentioned in the former paragraph) of the dilaton gravity on the dynamic phase transition of black holes. A small difference is also observed in the evolution time for the same$ \alpha $ . It takes longer for the small black hole to transition into the large black hole, which is related to the distance between$ r_m $ of the unstable and large (small) black holes.Figure 3. (color online) Time evolution of
$ \rho(r_l,t) $ and$ \rho(r_s,t) $ for charged dilaton black hole with$ b = 1,\; q = 1,\; P = 0.003 $ . (a)$ \alpha = 0.4 $ , (b)$ \alpha = 0.4 $ , (c)$ \alpha = 0.2 $ , (d)$ \alpha = 0.2 $ , (e)$ \alpha = 0 $ , and (f)$ \alpha = 0 $ . For the left three graphs, the initial condition is chosen as a Gaussian wave packet located at the large dilaton black hole state, while for the right three graphs, the initial condition is chosen as a Gaussian wave packet located at the small dilaton black hole state.$ \alpha $ 0 0.2 0.4 $ \Delta G_{L} $ 0.00115 0.00951 0.11993 Table 1. Height of the barrier
$ \Delta G_{\rm L} $ as a function of$ \alpha $ with$ b = 1,\; q = 1,\; P = 0.003 $ . -
To further investigate the dynamic phase transition of dilaton black holes, the first passage process was considered. This process describes how the initial black hole state approaches the intermediate transition state for the first time. To numerically investigate this process, both the reflecting boundary condition and absorbing boundary condition were imposed. Note that the absorbing boundary condition
$ \rho(r_m,t) = 0 $ [58] was imposed at the intermediate transition state with the horizon radius denoted as$ r_m $ .Through resolving the Fokker-Planck equation constrained by these two boundary conditions, the first passage process of charged dilaton black holes is displayed in Fig. 4. Similarly, the initial condition was chosen as a Gaussian wave packet located at the large dilaton black hole state for the left three graphs, while the Gaussian wave packet located at the small dilaton black hole state was chosen for the right three graphs. Regardless of the initial black hole state, the initial peaks decayed rapidly. We also compared the time evolution for different values of
$ \alpha $ . For the top, middle, and bottom rows of Fig. 4,$ \alpha $ values were chosen as 0.4, 0.2, and 0, respectively. From this, we observed that the initial peak decays more slowly with increasing$ \alpha $ , which is consistent with the results displayed in Fig. 2 and Fig. 3.Figure 4. (color online) Time evolution of
$ \rho(r,t) $ in the first passage process of a charged dilaton black hole with$ b = 1, \;q = 1, \;P = 0.003 $ . (a)$\alpha = 0.4 $ , (b)$ \alpha = 0.4 $ , (c)$ \alpha = 0.2$ , (d)$ \alpha = 0.2 $ , (e)$ \alpha = 0$ , and (f)$ \alpha = 0 $ . For the left three graphs, the initial condition was chosen as a Gaussian wave packet located at the large dilaton black hole state, while for the right three graphs, the initial condition was chosen as a Gaussian wave packet located at the small dilaton black hole state.The time needed for the first passage process is denoted as the first passage time. Its distribution
$ F_p(t) $ can be obtained via [57]$ F_p(t) = -\frac{{\rm d}\Sigma(t)}{{\rm d}t}, $
(12) where
$ \Sigma(t) $ is the sum of the probability of the black hole system not having completed a first passage by time t.Figure 5 shows the time evolution of
$ \Sigma(t) $ . Irrespective of the initial state,$ \Sigma(t) $ decays quickly. The effect of dilaton gravity can also be observed, with$ \alpha $ values chosen as 0.4, 0.2, and 0 for the top, middle, and bottom rows of Fig. 5, respectively. With increasing$ \alpha $ , the decay of$ \Sigma(t) $ slows down.Figure 5. Time evolution of
$ \Sigma(t) $ for charged dilaton black hole with$ b = 1, \;q = 1,\; P = 0.003 $ . (a)$ \alpha = 0.4 $ , (b)$ \alpha = 0.4 $ , (c)$ \alpha = 0.2 $ , (d)$ \alpha = 0.2 $ , (e)$ \alpha = 0 $ , and (f)$ \alpha = 0 $ . For the left three graphs, the initial condition was chosen as a Gaussian wave packet located at the large dilaton black hole state, while for the right three graphs, the initial condition was chosen as a Gaussian wave packet located at the small dilaton black hole state.$ F_p(t) $ can also be derived via Eqs. (11) and (12) as [58]$ F_p(t) = -D\frac{\partial \rho(r,t)}{\partial r}\Big|_{r_m}. $
(13) This distribution of first passage time is depicted in Fig. 6. Only a single peak is present in each graph of
$ F_p(t) $ , suggesting that the first passage process takes place very quickly. Additionally, the time corresponding to the peak increases with the parameter$ \alpha $ .Figure 6.
$ F_p(t) $ for charged dilaton black hole with$ b = 1,\; q = 1,\; P = 0.003 $ . (a)$ \alpha = 0.4 $ , (b)$ \alpha = 0.4 $ , (c)$ \alpha = 0.2 $ , (d)$ \alpha = 0.2 $ , (e)$ \alpha = 0 $ , and (f)$ \alpha = 0 $ . For the left three graphs, the initial condition was chosen as a Gaussian wave packet located at the large dilaton black hole state, while for the right three graphs, the initial condition was chosen as a Gaussian wave packet located at the small dilaton black hole state.
Dynamic phase transition of charged dilaton black holes
- Received Date: 2021-05-04
- Available Online: 2021-10-15
Abstract: The dynamic phase transition of charged dilaton black holes is investigated in this paper. The Gibbs free energy landscape is introduced, and the corresponding