Knowing the Origin of Cosmic Rays is very important for every one because it helps us understand our life in a better manner.
The question as to why these rays exist and what they do is not answered. However, knowing their nature and their functions is very important for the modern human being. The origin of cosmic rays deals with the most common cosmic ray phenomenon that forms the base of our entire solar system. This is the radiation we get from the sun that travels through the atmosphere to space.
Cosmic rays are highly energetic particles that originate from outer space and travel towards the earth from star systems. They constitute the basis of our universe and play a crucial role in the overall chemistry of space-based matter. The Origin of Cosmic Rays explains the various cosmic ray phenomena that lead to the production of particles called protons, neutrons and gamma rays.
The origins of these particles can be traced back to an explosion in the universe which created high-energy neutrally charged particles accelerated by a powerful magnetic field.
These accelerated particles were produced in great abundance during the rapid expansion phase of the universe which lasted billions of years. They originated at the edge of a spiral galaxy which is one of the few spiral structures known to exist. When scientists carry out research in this field, they often come across evidence that supports this view. This is particularly because the relic of an exploding super giant black hole is found to contain enormous amounts of neutral gamma rays that have been emitted in a recent collision.
Another school of thought proposes that the acceleration mechanisms used by the extra large hydrogen to create gamma-rays are completely different from those used by the Sun to produce visible radiation.
In fact, it is possible that the process used by the Sun may have been a secondary effect of the Big Bang Theory, according to this school.
Since the acceleration mechanisms for producing gamma rays from a very high temperature are similar to those used by the acceleration mechanisms for producing gamma rays from high solar temperatures, it is possible that the Sun was able to utilize such mechanisms at very high temperatures to produce its energy. Such theories are therefore not very controversial.
Another school maintains that the accelerated particles interact with neutral particles in the outer atmosphere of our earth.
Evidence for such interactions can be found in cosmic ray experiments carried out by teams from the University of Hawaii, Institute of Space and Technology, Tohoku University and others. The experiments show that the gamma rays traveling through the Earth’s atmosphere are deflected by various natural sources, including our own magnetic fields.
The study carried out by these teams indicates that the source of these cosmic rays is the result of a super giant merger of many smaller, low mass stars which happened to form very close to our own galaxy. Such merger was made possible by a relatively slow rotation, which took place at a time when our galaxy was in the infancy stage. During this period, the mass of gas that existed in our galaxy was much denser than it is today. This led to nuclei of different elements being pulled together by gravity and to form the first elements of the planet’s crust and atmosphere.
The scientists maintain that these smaller stellar bodies had no chemical make up when they first formed.
They obtained their strength from radioactive elements and from the heat given off by their nuclear explosions. When cosmic rays interact with neutral atoms they cause them to become excited, which in turn emits radiation. This process explains why the origin of cosmic rays can be identified with high accuracy by satellites and space based experiments.
The study also suggests that the fraction of nuclei that are neutralized by cosmic rays is greater at the southern sky than it is at the north.
This has implications for the composition of our solar system. Further evidence of this theory comes from the B-modes, which show that the total number of neutral elements is decreasing around the time of periapsis in our solar system. Radio astronomers have found that the fraction of electrons that are neutral, instead of protons, is increasing as a result of this change in the makeup of primordial gas.