The Doomsday Scenario: Collision of Antimatter Black Hole with the Largest Known Black Hole, TON 618

Introduction

The universe is brimming with mysteries, and one of the most elusive phenomena is the black hole. In recent years, scientists have discovered some incredibly massive and dense black holes, such as TON 618, the largest known black hole. Now, consider what would happen if an antimatter black hole with the mass of 105008.294 billion Jupiter masses were to collide with TON 618. This article explores the potential outcomes of such a cataclysmic event.

Understanding the Mass of the Antimatter Black Hole

Imagine a black hole with a mass equivalent to 105008.294 billion Jupiter masses. This black hole would be enormous, dwarfing even the most massive known celestial objects. The concept of an antimatter black hole introduces a new layer of complexity, as antimatter particles are identical in mass to their matter counterparts but have the opposite charge.

The Physics of Black Hole Collisions

When two black holes collide, they release a significant amount of energy in the form of gravitational waves, which can be detected by observatories. However, if one of these black holes is made of antimatter, the collision would have catastrophic consequences. The annihilation of matter and antimatter is a process where the mass of both is converted into pure energy, primarily in the form of gamma radiation.

Gamma Ray Observations and the Brightness Profile

Gamma ray observatories across the globe will be triggered to observe this event. The collision would produce a substantial amount of gamma radiation, which would travel through space at the speed of light. Observatories equipped with advanced radio technology would be particularly effective in detecting the bright and steady gamma ray emissions. The resulting light curve would be a powerful indicator of the violent annihilation taking place.

The Growth of the Black Hole

Despite the destructive nature of the collision, the resultant black hole would likely grow in size. After the formation of a black hole, its composition (whether made from a dead star, antimatter, or any other substance) does not significantly affect its future growth. The combination of the two black holes would create a larger, more massive black hole. This unfolding scenario is detailed in a video by “kugersat-in a nutshell” and you can watch it for a more detailed explanation.

Radio and Gravitational Waves

Black holes, whether made of matter or antimatter, emit radio waves and gravitational waves. These waves carry information about the black hole's properties, including its mass and spin. In the case of a collision, the emission of these waves would peak as the black holes merge, and continue to do so as the resulting black hole settles into a more stable state. The observation of these waves would provide valuable data for astrophysicists studying the nature of black holes.

Potential Aftermath and Consequences

The collision of a matter black hole and an antimatter black hole would be immensely destructive. The annihilation would release a vast amount of gamma rays, likely comparable to the energy output of billions of supernovae. This would have a profound impact on the surrounding region, potentially disrupting the orbits of nearby stars and planets and even creating a new black hole or leading to the birth of a more massive one.

The shockwave from the collision would be powerful enough to disperse and disrupt the orbits of celestial bodies in the vicinity. Additionally, it could trigger a gamma-ray burst, a powerful explosion that could travel billions of light-years through space. The aftermath of such an event would significantly alter the evolution of the surrounding galaxy.

Speculation and Current Understanding

It is important to note that these scenarios are speculative, as we have never observed a collision between a matter black hole and an antimatter black hole. However, based on our current understanding of physics and astrophysics, this is the most probable outcome. The study of black holes, especially those of extreme mass like TON 618, continues to fascinate and challenge scientists, pushing the boundaries of our knowledge and understanding of the universe.

Keywords: black hole collision, antimatter black hole, TON 618