Abstract

In this article we hypothesized that the arrow of time and space evolve in a discontinuous way in the form of quanta (t=nt_p, s=ml_p). We applied this reasoning to the light geodesics of Schwarzschild’s metric (ds_min=l_p) and obtained different characteristics of the BH. Indeed, quantum light geodesics show that inside the BH a WH is formed and the mass (energy) is not directing towards the singularity r→0 but rather around the BH near the EH as a thick skin (tickness ). The total relativistic energy invariant is satisfied for the entire route of the photons. Subsequently, as mass (energy) is found directly at the EH, we applied the quantum tunnel effect in simple semi-classical analysis, and we obtained that particles like protons can leave the EH and that the energy associated with them is in the order of magnitude of Hawking’s radiation. However, the energy of the protons is not necessarily identified with that of the black body (photonic or electromagnetic). Finally, it would be interesting to see the impacts of this quantum light geodesics (ds_min=l_p) on other cases like Kerr’s metric.

Keywords

Black Hole, White Hole, Schwarzschild Metric, Quantum Spacetime, Tunnel Effect

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1. Introduction: Formulation of the Model Initial Concept

The idea behind this article comes from a rather long reflection about the manufacture of the universe as well as a model of cosmology already published [1]. The prediction of the possible existence of black hole (BH) is not recent (John Michell in 1783, Pierre Simon de Laplace in 1796). Their properties, although often relatively abstract and difficult to grasp, are fascinating. Since then, a large number of physicists and mathematicians have continued to develop and understand what the characteristics of these strange objects might be complex and indirectly observed only once [2]. It was the general relativity (GR) theory as well as the first development of Schwarzschild that brought to light the main characteristics of these objects [3]. Subsequently, other developments and understanding were added to that of Schwarzschild, BH in rotation [4], charged electrically [5]. A large number of publications present the various theories relating to BH, we refer the reader to the thesis of Bardoux [6] which presents a good review of the BH metrics.

One of the fundamental problems related to the models of BH lies in the mathematical expression within them, which predicts that the energy within the event horizon (EH) invariably follows its movement towards a central singularity $r\to 0$. Although mathematical, this concentration of energy tending towards infinity to this singularity poses a problem or at least a plot. It is the infinite curvature of space, predicted by the metric of the GR that leads to this state of infinite concentration of energy.

The model proposed here (a quantum light geodesic metric) is based on the idea of quantifying two fundamental variables of the universe: space (the arrow of space increases confirmed by the expansion of the universe) and time (the arrow of time increases confirmed by observation) as proposed by the spacetime of the GR. The modern quantization of our understanding of the universe is approximately 120 years old from Planck (1900). Much effort has been made in the equation of quantum effects related to spacetime [7]. Closer to us, the theory of loop quantum gravity LQG develops a detailed understanding of this quantization of spacetime with the notions of loop, spin-network, foam [8]. In this article, we borrow a similar idea of the quantization of spacetime (quanta). Indeed, we accept that the notion of infinitesimal, when used in physical calculation in the context of algebraic or differential equations, imposes limit values as follows:

$\text{d}{s}_{\min }\ge l_P=\sqrt{\frac{hG}{2\pi c^3}}$ and $\text{d}{t}_{\min }\ge t_P=\sqrt{\frac{hG}{2\pi c^5}}$

This is the idea of quantas of space and time. As an example, the derivative that could be called quantum for this function would be:

$f\left(t\right)=a{t}^2$

${\frac{\text{d}f\left(t\right)}{\text{d}t}}_q=\underset{t\to t_P}{\lim }\frac{f\left(t+t_P\right)-f\left(t\right)}{t_P}=\frac{a{\left(t+t_P\right)}^2-a{t}^2}{t_P}=\frac{a\left(t^2+2t{t}_P+t_P^2\right)-a{t}^2}{t_P}$

${\frac{\text{d}f\left(t\right)}{\text{d}t}}_q=2at+a{t}_P$

It is clear that at the macroscopic scale, the correction $a{t}_P~{10}^{-43}a$ is negligible but for a very high value of a, as observed in cosmology or astrophysics (e.g. combination of Planck’s scale variables or high energy phenomenon), it is possible to obtain not insignificant quantum effect (see a state equation, Perron, 2021) [1]. For example, we also find:

$f\left(t\right)=\sin t$, ${\frac{\text{d}f\left(t\right)}{\text{d}t}}_q=\cos \left(t+\frac{t_P}{2}\right)$

$f\left(t\right)=\frac{1}{t}$, ${\frac{\text{d}f\left(t\right)}{\text{d}t}}_q=\frac{-1}{t^2+t{t}_P}$

For example, at the particle acceleration scale, if we consider the exchange of energy, we can estimate that the variation in total energy associated with the acceleration of the particle can be expressed as:

$P=\frac{\text{d}{E}_t}{\text{d}t}=\frac{\text{d}{E}_t}{\text{d}v}\frac{\text{d}v}{\text{d}t}$

$P_q={\frac{\text{d}{E}_t}{\text{d}t}}_q=\frac{\text{d}{E}_t}{\text{d}v}\frac{\text{d}v}{t_P}$

${\Delta }_q=\frac{\frac{\text{d}{E}_t}{\text{d}t}}{{\frac{\text{d}{E}_t}{\text{d}t}}_q}=\frac{\frac{\text{d}v}{\text{d}t}}{\frac{\text{d}v}{t_P}}=\frac{t_P}{\text{d}t}~\frac{{10}^{-43}}{{10}^{-15}}~{10}^{-28}$

Thus for phenomena of energy exchange in the order of the femtosecond (10⁻¹⁵ s), the quantum part of the experiment is worth ~10⁻²⁸ of the total which is still undetectable with today’s instruments ( [9] atomic clock precision $\Delta t~{10}^{-19}\text{s}$ ). In general, although it may seem strange, if we accept the quantification of fundamental variables such as time and space, in the field of physics (quantum scale), the notion of infinitesimal tends to zero ( $\Delta t\to 0$ ) associated with space and time does not exist. This idea of the non-existence of ( $\Delta x\to 0$ ) is compatible with Heisenberg’s uncertainty principle because it also delimits the notion of strict infinity that does not exist in physics either.

2. Schwarzschild Quantum Light Geodesic Metric (SCK)

The idea of quantum Schwarzschild metric KSC is not new [10] [11]. However, the way in which this quantization is done may differ depending on our understanding of quantification. For example, we can admit a small quantum variation of r proposed by Kazakov and get interesting results about the internal structure of the BH according to the choice of a quantum variation parameter a, which affect r. In this article, if we look at the energy part of the evolution of a physical phenomenon, we postulate that spacetime has the quantum characteristic even for light. In admitting this hypothesis of quantum spacetime, we must consider that the light geodesics, normally accepted as zero length in theory ( $\text{d}s\equiv 0$ or proper time $\tau \equiv 0$ ) are also quanta. Thus, for a Schwarzschild metric (spherical symmetry in the void), we find a priori,

$\begin{array}{l}{c}^2\text{d}{\tau }^2=\text{d}{s}^2=l_P^2=\frac{hG}{2\pi c^3}\\ \le -\left(1-\frac{R_s}{r}\right)c^2\text{d}{t}^2+{\left(1-\frac{R_s}{r}\right)}^{-1}\text{d}{r}^2+r^2\left(\text{d}{\theta }^2+{\sin }^2\theta \text{d}{\phi }^2\right)\end{array}$

With the radius of Schwarzschild $R_s=\frac{2GM}{c^2}$,

It should be noted here that this metric does not meet Minkowski’s metric (flat) $r\to \infty$. An amendment is required for this condition. This SCK light geodesic metric satisfies Minkowski.

$l_P^2\le -\left(1-\frac{R_s}{r}\right)c^2\text{d}{t}^2+2{\left(1-\frac{R_s}{r}\right)}^{-1}\text{d}{r}^2+r^2\left(\text{d}{\theta }^2+{\sin }^2\theta \text{d}{\phi }^2\right)$

Let’s do the developments to find the quantum light geodesics and other conclusions. For radial light geodesics, ( $\text{d}\theta =\text{d}\phi =0$ ) we find:

$\frac{l_P^2}{\text{d}{t}^2}=-\left(1-\frac{R_s}{r}\right)c^2+2{\left(1-\frac{R_s}{r}\right)}^{-1}\frac{\text{d}{r}^2}{\text{d}{t}^2}$

Based on our hypothesis of the quantization of spacetime, the element associated with $l_P$ the dt variable is considered the value of t_P (quanta), then,

$\frac{l_P^2}{t_P^2}=c^2=-\left(1-\frac{R_s}{r}\right)c^2+2{\left(1-\frac{R_s}{r}\right)}^{-1}\frac{\text{d}{r}^2}{\text{d}{t}^2}$

Isolate for the speed of photons, we find a remarkable equation:

$\frac{\text{d}{r}^2}{\text{d}{t}^2}=\frac{1}{2}\left(1-\frac{R_s}{r}\right)c^2+\frac{1}{2}{\left(1-\frac{R_s}{r}\right)}^2{c}^2$

either,

$\frac{\text{d}r}{\text{d}t}=\pm c\sqrt{\frac{1}{2}\left(1-\frac{R_s}{r}\right)+\frac{1}{2}{\left(1-\frac{R_s}{r}\right)}^2}$

For $r\to \infty$, we find Minkowski (flat),

$\frac{\text{d}r}{\text{d}t}=\pm c$

And for $r\to 2l_P$ (r minimal for this metric is $R_s^{\min }=2l_P$ ), we find:

$\frac{\text{d}r}{\text{d}t}\to \pm \infty$

The equations of quantum light geodesics ( $\text{d}s=l_P$ ) are of the form.

$c{t}_q=\pm {{\displaystyle \int }}^{\text{}}\frac{\sqrt{2}\text{d}r}{\sqrt{\frac{R_s^2}{r^2}-\frac{3R_s}{r}+2}}$

either,

$c{t}_q=\pm \frac{\sqrt{2}}{2}\sqrt{R_s^2-3R_{s}r+2r^2}\pm \frac{3}{4}\ln \left[2\sqrt{2}\sqrt{R_s^2-3R_{s}r+2r^2}+4r-3\right]+C$

Figure 1 shows the photons quantum light geodesics according to the $+\text{d}r/\text{d}t$ (leaving photons) of the conventional Schwarzschild metric and the quantum one. First, we find that the quantum light geodesics are well defined for $r\ge R_s$. Second, the quantum light geodesics are not defined for $\frac{R_s}{2}<r<R_s$ because the value of the radical is negative and the logarithm argument is negative. Third, for the value of $r<\frac{R_s}{2}$ the values of geodesics are partially defined

(the radical is positive but the argument of the logarithm is negative). Finally, we see that for the BH zone $\frac{R_s}{2}<r<R_s$ the spacetime is not defined precisely as usual. At $r=R_s$ the variation is less rapid. Then, for the quantum case, the photons cross the EH more slowly and remain in this zone between $\frac{R_s}{2}<r<R_s$. The mass (energy) is stacked “layer per layer” from the outside during the growth of the BH. The geodesics are vertical for $r=R_s$ and $\frac{R_s}{2}$. However, the photons are no longer rotating as strongly on the EH. This element could be a characteristic to validate this metric.

Figure 2 shows the photons speed. We have a particular zone $\frac{R_s}{2}<r<R_s$ for which the speed is undetermined (imaginary) but on both sides, the speed v is worth 0. This zone is like the elongated extension of the point $r=R_s$. This zone included $\frac{R_s}{2}<r<R_s$ could accumulate energy because we observe the speed is positive at $r<\frac{R_s}{2}$ a theoretically empty zone of energy

that has the characteristics of a white hole WH ( [12] a central spherical zone where matter (energy) is ejected outside towards the edge of the BH zone). This notion of WH within the BH is special because it allows to contain the WH in the BH and avoid the explosion of the WH, an idea already envisaged [13]. However, what is special here is the existence of a WH within a BH.

This inner zone $\frac{R_s}{2}<r<R_s$ could be a Cauchy horizon zone but this needs to be evaluated. In other words, for this SCK light geodesic metric, the energy is not directed towards the center at $r\to 0$ (singularity) but for an area around the edge near the EH (a thick skin $\frac{R_s}{2}$ or a ring of the BH rather than a membrane at $R_s$ ).

One can evaluate whether the total relativistic energy invariant is satisfied in this zone, $\frac{R_s}{2}<r<R_s$, either,

$\frac{E^2}{c^2}-p^2=m^2{c}^2$

with

$E^2={\gamma }^2{m}^2{c}^4=\frac{m^2{c}^4}{1-\frac{v^2}{c^2}}$

$p^2={\gamma }^2{m}^2{v}^2=\frac{m^2{v}^2}{1-\frac{v^2}{c^2}}$

$v^2=c^2\left(\frac{1}{2}\left(1-\frac{R_s}{r}\right)+\frac{1}{2}{\left(1-\frac{R_s}{r}\right)}^2\right)=c^2\left(1-\frac{3R_s}{2r}+\frac{R_S^2}{2r^2}\right)=c^2\Psi \left(r,R_s\right)$

Let’s substitute the expression of $v^2$ in the invariant equation we find:

$E=\frac{m{c}^2}{\sqrt{1-\Psi }}$, $p=\frac{\sqrt{\Psi }mc}{\sqrt{1-\Psi }}$

$\frac{E^2}{c^2}-p^2=\frac{m^2{c}^2}{1-\Psi }-\frac{m^2{c}^2\Psi }{1-\Psi }=m^2{c}^2\frac{1-\Psi }{1-\Psi }=m^2{c}^2$

Thus, we see that the total relativistic energy invariant is satisfied for the entire course of the photon including this particuliar zone. The result is remarkable since this quantum light geodesics properly satisfied the total relativistic energy, but the photons have imaginary speed in the BH zone and an imaginary momentum p. An imaginary momentum is not possible in quantum mechanics because it’s a measurable quantity, but this BH zone is unconventional in terms of spacetime and in addition, we can not measure anything in this BH zone. Also, the Lorentz factor in this BH zone is less than 1 ( $\gamma <1$ ) which is strange because not conform to $E_{\min }=m{c}^2$. This corresponds to a proper time ∆τ in this zone which is greater than ∆t outside this BH zone (inverse of normal case). This BH zone looks like a cavity where the energy is trapped, and the laws of physics seem partially different. However, electromagnetic energy is not necessarily in the conventional state.

The solution found corresponds in part to that found with the so-called Einstein-Gauss-Bonnet (EGB) approach. Indeed, this approach makes it possible to find different solutions in the case of BH. In particular, [14] Glavan et al., using this EGB approach, show that a solution predicts the existence of 2 horizons $r_{\pm }^H$ according to the value of a parameter $\alpha$ ( $\alpha \ge 0$ ) either.

$r_{\pm }^H=\frac{R_s}{2}\left[1\pm \sqrt{1-\frac{16\pi \alpha }{G{M}^2}}\right]$

For $\alpha =0$, we find the SC case of the GR, either an EH at $R_s$. For $\alpha =\frac{G{M}^2}{16\pi }$ we find an EH at $\frac{R_s}{2}$. Finally for $0<\alpha <\frac{G{M}^2}{16\pi }$ we find 2 horizons and the appearance of a WH for $0<r<r_{-}^H$. However, we see that the horizons found $r_{\pm }^H$ do not exactly match those found with this SCK.

With this SCK metric, it allows us to better understand the distribution of energy in the BH since this energy is not directed towards the singularity but towards a physical zone near the EH. We can estimate the energy density of such a BH in the area $\frac{R_s}{2}<r<R_s$, either.

$\rho =\frac{M}{V}=\frac{M}{\frac{4}{3}\pi \left(R_s^3-{\left(\frac{R_s}{2}\right)}^3\right)}=\frac{M}{\frac{28\pi G^3{M}^3}{3c^6}}=\frac{3c^6}{28\pi G^3{M}^2}$

Thus, the density decreases with the increase in mass M as is the case of the conventional SCH and it is independent of the size. According to this metric, there is no limit to the growth of BH in terms of mass. Considering that the miminal radius of the BH is in order $2l_P$ (inner WH and outer BH zone), we find that the maximum energy density of such a WH-BH pair is:

${\rho }_{\max }=\frac{3}{32\pi }{\rho }_{\text{Planck}}$

In regards to the state of energy (matter) in the BH zone, it is possible to try to determine this state which corresponds in part to a gas in a cavity. For fermions, it can be thought that matter follows the Fermi-Dirac statistic at very low temperature would be in a degenerate state with minimum energy ${\epsilon }_0$ occupied by fermions. The parameters $E_F,T_F,P,p,S$ for N electrons, protons and neutrons in volume V of gas using this statistic can be estimated, but the results would be purely speculative [15].

An important point is to be emphasized. Indeed, given this central area of the type WH, the complete evaporation of the BH seems possible without leaving a singularity to $r=0$ because the energy does not get to the point $r=0$. Ideed, one can imagine that the last mass part of the BH is evaporated and the WH explodes at the end without any energy involved.

Figure 3 shows a schematic of the formation of a BH and WH with this quantum light geodesic. In ${t^{\prime }}_0$ the collapse begins. An EH is created at ${t^{\prime }}_1$ and the formation of a BH and WH begin. In ${t^{\prime }}_2$ the process is completed and the

final mass of the BH produces a radius $R_s$ and a WH of radius $\frac{R_s}{2}$.

A more detailed simulation would allow us to better see the appearance of such a BH. It is important to note that all parameters outside the EH are the same for the SCK light geodesic metric (spherical symmetry for $r>R_s$ ). In addition, SCK light geodesic metric predicts energy near the border of the EH.

3. Hawking Temperature and BH Evaporation by Tunnel Effect

In 1975, Hawking proposed an ingenious mechanism of energy evaporation of BH that he attributes to a quantum effect of creating particles and antiparticles [16]. With this metric, energy (mass) remains near on the EH, which allows us to imagine a process of energy evaporation of BH by the quantum tunnel effect [17] [18]. To illustrate the process, a semi-classical estimate of this effect can be made. If the mass is made up mainly of hadron (proton) and a quantum tunnel effect allows a tiny amount to pass beyond the EH, we can estimate the energy emitted by the BH with the quantum tunnel effect by knowing the energy of the emitted particle as well as the number. Let’s say an energy barrier inside the EH as U of few diameters of the protons $=n{r}_p$. A first simplified model of quantum tunnel effect transmission through a rectangular barrier predicts a T transmission factor [19].

$T=t^2=\frac{4K^2{k}^2}{{\left(K^2+k^2\right)}^2{\text{sinh}}^2\left(Kd\right)+4K^2{k}^2}$

with: $K=2\pi \sqrt{2m_p\left(U-E_p\right)}/h$

$k=2\pi \sqrt{2m_p{E}_p}/h$

In the case of the BH and this tunnel effect, the kinetic energy is that of the protons E_p estimated by the internal energy of the proton at very low Hawking temperature. The barrier is the gravitational U energy at the EH to release a particle $r\to \infty$ (proton). The value of the energy transmitted must be that of Hawking’s radiation ${\stackrel{\dot{}}{E}}_H$ at Hawking’s temperature $T_H$ (evaporation). Let’s evaluate the tunnel effect, the proton’s energy.

$E_p=\pi k_B{T}_H$

$U=\left|\sqrt{1-\frac{R_s}{r\to R_s}}-1\right|\frac{1}{\sqrt{1-v^2/c^2}}{m}_p{c}^2~m_p{c}^2$

$\dot{E_H}=A\sigma T_H^4$

For example, we could estimate the parameters of the quantum tunnel effect for the BH of M87 assuming a static BH, we find the following parameters:

$M~6.5M_{\odot }=1.287\times {10}^{31}\text{kg}$

$R_s=1.9\times {10}^{13}\text{kg}$

$T_H=9.53\times {10}^{-18}\text{K}$

${\stackrel{\dot{}}{E}}_H=2.15\times {10}^{-48}\text{W}$

$E_p=4.13\times {10}^{-40}\text{J}$

$U\sim 1.50\times {10}^{-10}\text{J}$

$K=6.72\times {10}^{15}{\text{m}}^{-1}$

$k=1.11\times {10}^1{\text{m}}^{-1}$

$d~6r_p\text{m}$

We find the transmission factor.

$T=1.52\times {10}^{-58}$

We find that the probability of proton transmision over the EH is extremely low but the number of protons, near the EH is very high. Suppose the kinetic energy of the protons without the barrier U i.e. without the BH and without the gravitation. Protons are free. The possibility of motion of protons can be done in both directions. 50% r₋ and 50% r₊. Thus, the possible proton flow towards $r\to \infty$ (without BH) is.

$\stackrel{\dot{}}{m}~\frac{1}{2}\rho Av~\rho 2\pi R_s^{2}v$

with ( $v\ll c$, non relativistic)

$v~\sqrt{\frac{2E_p}{m_p}}~7.03\times {10}^{-7}\text{m}\cdot {\text{s}}^{-1}$

$\rho =\frac{3c^6}{28\pi G^3{M}^2}~0.502\text{kg}\cdot {\text{m}}^{-3}$

We find,

$\stackrel{\dot{}}{m}~8.11\times {10}^{20}\text{kg}\cdot {\text{s}}^{-1}$

However, considering a tunnel effect with a barrier U ( $d=6r_p$ ) we find this fraction of transmitted proton.

${\stackrel{\dot{}}{N}}_{pT}=\frac{T\stackrel{\dot{}}{m}}{m_p}=7.37\times {10}^{-11}{\text{s}}^{-1}$

Finally, the energy emitted by tunnel effect to temperature $T_H$ expresses itself as.

${\stackrel{\dot{}}{E}}_{pT}={\stackrel{\dot{}}{N}}_{pT}{E}_p=7.37\times {10}^{-11}{\text{s}}^{-1}\times 4.13\times {10}^{-40}\text{J}=3.04\times {10}^{-50}\text{W}$

If we compare it with Hawking’s radiation, we find.

$\frac{{\stackrel{\dot{}}{E}}_{pT}}{{\stackrel{\dot{}}{E}}_H}=\frac{3.04\times {10}^{-50}\text{W}}{2.15\times {10}^{-48}\text{W}}~0.014$

The value found is relatively well predicted given the uncertainty surrounding the tunnel effect (type, particle, barriers, others). The ratio can be changed by changing the thickness of the barrier d. The value found changes rapidly with the thickness of the barrier. With this tunnel effect, the BH of M87 will be evaporated for a time.

$t_{eva}=\frac{M}{T\stackrel{\dot{}}{m}}~\frac{1.287\times {10}^{31}\text{kg}}{1.23\times {10}^{-37}\text{kg}\cdot {\text{s}}^{-1}}~{10}^{77}\text{s}~{10}^{60}\text{Gy}$

Figure 4 shows the effects of the thickness of the barrier d in terms of the radius of the proton on the ratio of energy evporated $\frac{{\stackrel{\dot{}}{E}}_{pT}}{{\stackrel{\dot{}}{E}}_H}$ ratio for a variation in

the BH mass from $6.5M_{\odot }$ to $6.5\times {10}^9{M}_{\odot }$. We see that, despite the great variation in the mass of the BH, the size of the quantum barrier varies very little for the desired ratio of 1. However, this example of tunnel effect predicts a free proton transfer to the other side of the EH, which is not necessarily black body radiation as predicted by Hawking’s theory (electromagnetic). Finally, the value $d~6r_p$ that yields the ratio close to 1 does not have a particular justification.

4. Gravitational Wave and Validation of This Quantum Light Geodesic Metric

The detection of GW150914 gravitational waves in 2016 [20] has given rise to several explanations and simulations of the collision of BH with inspiraling process according to a numerical approach called post-Newtonian [21]. One approach is to consider the masses as a point source [22]. A mass, called chirp mass M, had been calculated which allows to estimate the masses of the two bodies in mutual m₁ et m₂ rotation. This SCK light geodesic metric predicts that the energy of the BH is located around the edge of the EH, which is a major difference that does not allow the masses to be considered as point sources when the collision occurs. This energy distribution around rotating BH could be a special signature to validate this metric when observing gravitational waves from the fusion of 2 BH. Indeed, if the received signal takes a particular form (amplitude or frequency deformation longer duration) when the separation of the BH will be that of the ~R_s largest, then it could be an indication that the energy is well around and the fusion leads to a reorganization of the energy around the new EH of the new BH formed. The observed and filtered signal clearly distinguishes a state of reorganization when the separation radius decreases beyond what could confirm the presence of energy in the zone of 1 to 1.5 R_s (see Figure 2 of Abbott et al., 2016 [20] ). Indeed, for a central energy concentration, the measured signal should show a continuous increase up to say near $r\to 0$ while we see a decrease towards $r\to 1~1.5R_s$. The future will certainly allow us to better understand the merging effects of BH and to determine more precisely the internal nature of BH.

5. Conclusion

In this article we hypothesized that the arrow of time and space evolve in a discontinuous way in the form of quanta ( $t_P,l_P$ ). We applied this reasoning to the light geodesics of Schwarzschild’s metric and obtained different characteristics of the BH obtained. Indeed, quantum light geodesics show that inside the BH a WH is formed, and the mass (energy) is not directing towards the singularity $r\to 0$ but rather around the BH near the EH as a thick skin. Subsequently, as mass (energy) is found directly at the EH, we applied the tunnel effect in simple semi-classical analysis, and we obtained that particles, like protons, can leave the EH and that the energy associated with them is in the order of magnitude of Hawking’s radiation. However, the energy of the protons is not necessarily identified with that of the black body (electromagnetic). Finally, it would be interesting to see the impacts of this quantum light geodesics ( $\text{d}s=l_P$ ) on other cases like Kerr’s metric.

6. Funding Statement

Funding for this article was supported by the University of Quebec at Chicoutimi.

Acknowledgements

The author would like to thank the members of his family, especially his spouse (Danielle) as well his childrens (Pierre-Luc, Vincent, Claudia). Finally, thanks to the University of Quebec at Chicoutimi and to the colleagues of the Department of Applied Sciences for their supports in the realization of this work.

Conflicts of Interest

The author declare no conflicts of interest regarding the publication of this paper.

References