EVENT HORIZON 

IS NOT 

SCHWARZSCHILD RADIUS 

MIRCEA BIDIAN
Independent Researcher 

This year marks the 100th anniversary of the solar eclipse that made Albert Einstein famous, thanks to the experiment conceived in 1917 by Sir Frank Watson Dyson, the Astronomer Royal of Britain, Sir Arthur Eddington, who led the experiment, and Andrew Crommelin, who led the Brazilian team.

From the very beginning of modern physics, there were suspicions that light could be distorted in a strong gravitational field. At the end of his treatise Opticks (1704), Isaac Newton pondered the question:

Do not Bodies act upon Light at a distance, and by their action bend its rays, and is not this action (cæteris paribus) strongest at the least distance?

In 1783, English philosopher John Mitchell argued that light—which, according to Isaac Newton, should be made up of tiny corpuscles—does not always travel in straight lines but can be deflected by the gravitational pull of a body. Around 1784, Henry Cavendish calculated the deflection of light by a massive body, assuming Newton's corpuscular theory of light and the law of gravity. He never published his result, but a rough draft of his calculations remains as proof. John Mitchell went even further. He described a massive star whose gravity was so great that the light corpuscles emitted by the star would fall back onto its surface. John Mitchell effectively described what we now call a black hole, a term first used in written literature by Ann Ewing in 1963 and popularized by John Wheeler in 1967.

Just a few years later, in 1796, French mathematician Pierre-Simon Laplace, independently of John Mitchell, suggested that there could be bodies with such a strong gravitational force that light could not escape from them. Laplace calculated such an object and found that the total mass of the Sun would have to be contracted into a sphere just six kilometers in diameter. In 1801, astronomer J. Soldner published an article titled Über die Ablenkung eines Lichtstrahls von Seiner Geradlinigen Bewegung durch die Attraktion eines Weltkörpers, where he investigated the error in determining the angular positions of stars due to the deflection of light. He calculated the orbit (which was, in fact, a hyperbola) of a body moving at the speed of light \(c\) as it passed near a spherical mass \(M\) with radius \(r\), obtaining a deflection angle of 0.875 arcseconds.

In 1911, Albert Einstein performed similar calculations to find the deflection angle, obtaining a value of 0.83 arcseconds, and the equation below:

\[\varphi=\frac{2GM}{c^2 r}[m]\]

which brought him very close to Soldner's result, calculated 110 years earlier. However, the solar eclipses of 1912 in Brazil and August 21, 1914, in Kiev and Crimea were doomed to failure due to bad weather and the onset of World War I. Looking back at these experiments, one could say that it was fortunate for Einstein, as the results would not have supported his theory if the eclipse photography had succeeded.

On December 20, 1915, Einstein received a letter from Karl Schwarzschild, containing a mathematical solution in polar coordinates that would later be known as the Schwarzschild solution or Event Horizon for black holes. Einstein himself presented this solution to the Prussian Academy of Sciences. The equation's solution is:

\[r_S=\frac{2GM}{c^2}[m]\]

where \(r_S\) is the Schwarzschild radius, \(G\) is the gravitational constant, \(M\) is the mass of the black hole, and \(c\) is the speed of light in a vacuum. If the radius of the central body is smaller than the Schwarzschild radius, this represents the point beyond which all massive objects, even light, must inevitably fall into the central body (ignoring quantum tunneling effects near the boundary). When the mass density of this central body exceeds a certain threshold, it triggers a gravitational collapse, which, if spherical symmetry is preserved, produces what we call a Schwarzschild black hole. Of course, this solution applies to a black hole with zero rotational spin.

In May 1916, Einstein published his essay The Foundation of the General Theory of Relativity in Annalen der Physik, where the value of the deflection angle was 1.75 arcseconds, double what he had calculated in 1911 and what Soldner had obtained in 1801. On March 8, 1919, two expeditions set out for different destinations: Sir Arthur Eddington to the island of Príncipe in Africa and Andrew Crommelin to Sobral in Brazil, for the solar eclipse on May 29, 1919. Sir Eddington managed to take 16 photographs, of which only two were usable, and Andrew Crommelin took 8 usable photographs.

Once the teams returned to England, work began on evaluating the photographic plates. A preliminary result from Sir Eddington in September 1919 was followed by Crommelin's final result on November 6, where the values from one telescope were 1.98 ± 0.18 arcseconds and 1.60 ± 0.31 arcseconds from the second telescope. All the newspapers of the time marked the event on November 7. Due to persistent doubts over time about Sir Eddington's result, the photographic plates were remeasured in 1979 using modern instruments, and the result of 1.90 ± 0.11 arcseconds confirmed the value announced in 1919. Although these early measurements were not very precise (with errors of around 30% for the deflection angle), Newtonian values were clearly ruled out. The general theory of relativity had passed the test.

The deflection angle of light near the Sun has a value of 1.75 arcseconds and can be calculated using the formula below:

\[\varphi=\frac{4GM}{c^2 r}[m]\]

With the publication in December 2013 of the essay Gravitational Blue Shift Confirms the New Phenomenon of the Vertical Aether Flow into any Mass, authors M. E. Isma'eel and Sherif M. E. Ismaeel indirectly succeed in amending the Schwarzschild solution. The purpose of their essay was to demonstrate the vertical flow of æther into any mass, offering a solution derived directly from Einstein's grazing angle equation, as published in The Foundation of the General Theory of Relativity. In addition to correcting the Schwarzschild solution, the essay also demonstrates what gravity truly is. Of course, this idea is not entirely new; as early as 1853, Bernhard Riemann stated that gravitational æther is an incompressible fluid that flows into matter. Proportional to the mass of bodies, a current arises and carries all surrounding objects toward the central mass. Riemann speculated that the absorbed æther is transferred into another world or dimension. Accepting Riemann's conjecture along with the mathematical solution for the flow of æther into any mass, we have clear evidence that the existence of a light deflection angle (grazing angle) is a consequence of this phenomenon.

The Schwarzschild radius has remained a reference point to this day, without much effort to explore other solutions, even though relativistic calculations provide entirely different results. Upon analyzing the aforementioned essay, I noted the authors' observation regarding the discrepancy between the Schwarzschild radius and their own results, which caught my attention and prompted me to take a step further in seeking the real solution to the Event Horizon. I have no hesitation in affirming that the authors' solution is correct only for Sun, as it is derived directly from the grazing angle equation and was first confirmed in 1919. However, I assert that the Event Horizon solution I have found is the accurate one, although it would not have been possible without the groundwork laid by the authors. 

To ensure full understanding, I will also reproduce and explain the key points from Gravitational Blue Shift Confirms the New Phenomenon of the Vertical Aether Flow into any Mass. Essentially, the authors found two solutions for calculating the æther flow, but since the first solution, which uses the Doppler effect as a reference, does not seem conclusive to me, I will focus only on the second solution, which is based on Einstein's grazing angle equation. The diagrams below are sufficiently illustrative to allow for a detailed explanation of the phenomenon.

As can be seen in the figure above, we have an isosceles triangle, where the two sides \(c\) and \(c'\) are considered equal, with a value of 299,792,458 meters. Of course, in reality, \(c'\) is not a straight line but a hyperbola. However, for a distance of one light second, the error is negligible. The hypotenuse of the triangle, \(V_{æ}\), represents the æther flow velocity and is calculated using the following equation:

\[ V_{æ}=c\cdot 2\sin\left(\frac{\alpha}{2}\right)\approx c\cdot 2\cdot\frac{\alpha}{2}=c\alpha \]

Here, \(\alpha\) is the incident angle [rad], and the downward velocity of the æther flow \(V_{æ}\) is the product of the incident angle \(\alpha\) and the speed of light \(c\), giving \(V_{æ} = \alpha c \, [\text{m/s}]\). As we can see, the grazing angle equation and the equation above are equal and take the following form:

\[\frac{V_{æ}}{c} = \frac{4GM}{c^2 r}\]

This provides the solution for the downward velocity \(V_{æ}\) of the æther flow:

\[V_{æ} = \frac{4GM}{c r} \, [m/s]\]

In my view, this solution, valid for the Sun, solves a great mystery and answers the major question about the origin of gravity. Bernhard Riemann's conjecture from 160 years ago is now confirmed, yet modern science continues to ignore this essay.

Just one month ago, on April 11, 2019, an impressive piece of news made headlines—the first-ever photograph of a black hole, located at the heart of the M87 galaxy. At the end of this post, I will provide a calculation for this black hole.

The logic behind this suggests that at the point known as the Event Horizon, the æther velocity must equal the speed of light, preventing any event occurring within the black hole from escaping. As demonstrated above, æther—this space-time continuum, or quantum space—flows into every mass and creates the phenomenon we call gravity. Below, I will present the equations that the authors of the essay overlooked. Therefore, considering that the Event Horizon occurs at a radius \(r\) from the center of the black hole, where the speed of light and the downward æther flow velocity \(V_{æ}\) are equal, the equation takes the form:

\[r = \frac{GM}{V_{æ} c} \, [m]\]

or:

\[r = \frac{GM}{c^2} \, [m]\]

This last equation is the correct version for calculating the Event Horizon.

To conclude this post, I will calculate the Event Horizon for the black hole at the center of the M87 galaxy.

Problem data:

The mass of the black hole is estimated at \(6.5 \times 10^9 M_{\odot}\) (solar masses). The gravitational constant is denoted by \(G\), and the speed of light by \(c\).

\[\text{M87 mass} = 6.5 \times 10^9 M_{\odot} = 1.98847 \times 10^{30} \times 6.5 \times 10^9 = 1.2925055 \times 10^{40} \, [kg]\]

\[r = \frac{G \times 1.2925055 \times 10^{40}}{c^2} = 9.594 \times 10^{12} \, \text{m} \, [\text{Event Horizon}]\]

\[\frac{9.594 \times 10^{12}}{c} = 32,002 \, \text{light seconds} = 8h53'22''\]

To put this into perspective, the distance between the Sun and Pluto is around 7 light hours.