Ringing of the Regular Black Hole with Asymptotically Minkowski Core
Abstract
:1. Introduction
2. Regge–Wheeler Potential
- Spin one vector field: The conformal invariance of spin one massless particles in dimensions implies that the term vanishes, and indeed mathematically the potential reduces to the highly tractableSpecialising to the dominant multipole number gives:Now, in order to examine the qualitative features of the potential it is of mathematical convenience to define the new dimensionless variables , and . It is worth noting here that convention in the historical literature would be to set , such that the newly introduced scalar parameter appeals to the quantum gravity regime. This would imply that . In view of the redefinition of parameters, Equation (15) may be re-expressed as follows:The qualitative features of are then plotted in Figure 1, for the full range of y such that the spacetime still possesses a nontrivial horizon structure, and the domain for x such that one is strictly outside the horizon.An immediate sanity check from Figure 1 is that for , where the candidate spacetime reduces to Schwarzschild, one observes a peak at . This is the expected location of the photon sphere for Schwarzschild, and is indeed the corresponding location of the peak of the relevant spin one RW-potential. As a increases, the r-coordinate location of the peak decreases. For all values of a, there is falloff at spatial infinity, and once the peak is crested there is rapid falloff as one approaches the horizon location (where the RW-potential vanishes completely). The green line present in Figure 1b corresponds to the approximate location of the photon sphere calculated in reference [42]; . This approximation is used for the location of the peak of the spin one potential in order to extract the QNM profile approximations in Section 3. One can see that for the given domain and range this approximation has high accuracy, closely matching with the locations of the peaks.
- Spin zero scalar field: The potential now becomesOnce again, to examine the qualitative features of the potential it is convenient to re-express this in terms of the dimensionless variables :The qualitative features of are then displayed in Figure 2.The most notable feature is the spin zero peak; we see a slight shift in the peak locations between the spin one and spin zero potentials. The green line in Figure 2b is a ‘line of best fit’, obtained via manual corrections starting from the approximate location of the photon sphere as found in reference [42], and marks the a-dependent coordinate location . Given one does not have information concerning how the peak shifts when comparing the spin one and spin zero potentials a priori, and the peak location is not analytically solvable (see Section 3), this approximation is the best one can do in order to retain the desired level of mathematical tractability. Consequently, in Section 3, the approximation for as above is used in the computation of the relevant QNM profiles. The remaining features of the plot are qualitatively similar to those for the spin one case.
- Spin two bivector field (axial mode): The potential becomesOnce again, it is informative to re-express this in terms of the dimensionless variables , , givingThe qualitative features of are then displayed in Figure 3.Once again the approximate location for the peak of the spin two (axial) potential is obtained via application of manual corrections to the approximate location of the photon sphere as obtained in reference [42], and is found to be (this is the green line in Figure 3b). This approximation would serve as a starting point to extract QNM profile approximations for the spin two axial mode, similarly to the processes performed for spins one and zero in Section 3. However, for a combination of readability and tractability, this is for now a topic for future research. The remaining qualitative features of the spin two (axial) potential are similar to those for spins one and zero.
3. First-Order WKB Approximation of the Quasi-Normal Modes
3.1. Spin One
3.2. Spin Zero
4. Numerical Results
4.1. Spin One
- As a sanity check, for all values of , indicating that the propagation of electromagnetic fields in the background spacetime is stable—an expected result;
- increases monotonically with —this is the frequency of the corresponding QNMs;
- decreases with initially, up until , and then it increases monotonically with for the remainder of the domain—this is the decay rate or damping rate of the QNMs;
- Given that throughout the historical literature, it is conventional to assert , it is likely of primary interest to examine the behaviour of this plot for small . In view of this, if one constrains the analysis of the qualitative behaviour for prior to the trough present in Figure 4, one would expect that the signals for electromagnetic radiation propagating in the presence of a regular black hole with asymptotically Minkowski core should have both a higher frequency as well as a faster decay rate than their Schwarzschild counterparts. This qualitative result may translate to the spin two case, and speak directly to the LIGO/VIRGO calculation. The fact that the signal is expected to be shorter-lived could present a heightened level of experimental difficulty when trying to delineate signals, though this may very well be offset by the fact that the signal also carries higher energy; further discussion on these points is left to both the numerical relativity and experimental communities.
4.2. Spin Zero
- once again increases monotonically with —higher -values correspond to higher frequency fundamental modes;
- for all , indicating that the s-wave for minimally coupled massless scalar fields propagating in the background spacetime is stable;
- decreases with initially (down to a trough around ), before monotonically increasing with for the rest of the domain—this is the decay/damping rate of the QNMs;
- Similarly as for the electromagnetic spin one case, when one examines the behaviour for small , the signals for the fundamental mode of spin zero scalar field perturbations in the presence of a regular black hole with asymptotically Minkowski core are expected to have a higher frequency and to be shorter-lived than for their Schwarzschild counterparts.
4.3. Comparison with Bardeen and Hayward
- For the fundamental mode of the spin zero scalar s-wave for the Bardeen regular black hole, as deviation from Schwarzschild increases, increases and decreases. The signals are hence expected to have higher frequency but be longer-lived than for their Schwarzschild counterparts;
- For the fundamental mode of the spin zero scalar s-wave for the Hayward regular black hole, as deviation from Schwarzschild increases, both and decrease. The signals are hence expected to have lower frequency and be longer-lived than for their Schwarzschild counterparts.
5. Perturbing the Potential—General First-Order Analysis
- First, the position of the peak shifts:Performing a first-order Taylor series expansion of the left-hand-side of Equation (50) about then yields
- Secondly, the height of the peak shifts:
- Third, the curvature at the peak shifts
6. Conclusions
Funding
Acknowledgments
Conflicts of Interest
References
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WKB Approx. for | |
---|---|
0.287050–0.091235i | |
0.293902–0.092012i | |
0.301291–0.092532i | |
0.309304–0.092708i | |
0.318051–0.092419i | |
0.327658–0.091486i | |
0.338285–0.089636i | |
0.350117–0.086433i | |
0.363377–0.081139i | |
0.378330–0.072338i | |
0.395289–0.056624i |
WKB Approx. for | |
---|---|
0.187409–0.094054i | |
0.189734–0.094530i | |
0.191948–0.094669i | |
0.194049–0.094425i | |
0.196027–0.093742i | |
0.197868–0.092557i | |
0.199552–0.090796i | |
0.201042–0.088385i | |
0.202285–0.085306i | |
0.203235–0.081735i | |
0.203894–0.078421i |
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Simpson, A.M. Ringing of the Regular Black Hole with Asymptotically Minkowski Core. Universe 2021, 7, 418. https://doi.org/10.3390/universe7110418
Simpson AM. Ringing of the Regular Black Hole with Asymptotically Minkowski Core. Universe. 2021; 7(11):418. https://doi.org/10.3390/universe7110418
Chicago/Turabian StyleSimpson, Alexander Marcus. 2021. "Ringing of the Regular Black Hole with Asymptotically Minkowski Core" Universe 7, no. 11: 418. https://doi.org/10.3390/universe7110418
APA StyleSimpson, A. M. (2021). Ringing of the Regular Black Hole with Asymptotically Minkowski Core. Universe, 7(11), 418. https://doi.org/10.3390/universe7110418