One of the greatest explosions in the universe.
By blasting supernovas, stars can throw out all of these old home stock and become scattered cosmic dust.
In accordance with established practice, the concept has been adopted.
First of all, let’s say that the universe was created by a Big Bang.
A long time ago, there was a point, and it exploded!
A bunch of basic particles, like protons, electrons, neutrons, etc., are the ones described in the basic particle model.
This is the first universe, no stars, no planets, just particles.
Subsequently, work began on the laws of physics, with the basic particles coming together to form atoms.
Because the protons are positive, the electrons are negative.
So, of course, the easiest combination is protons and electrons, and that’s hydrogen atoms.
Sometimes both protons come together, forming helium atoms. But the more protons, the harder it is to form atoms together, after all, the protons are positive and mutually exclusive.
Thus, the vast majority of the atoms in the universe were hydrogen atoms and helium atoms, of which hydrogen atoms had only one proton, and thus accounted for most of the great majority.
In short, the universe was full of enormous hydrogen, and there were no celestial bodies.
With all gravity, the hydrogen that disperses in the universe attracts each other, pulls together, and gradually creates gas.
The larger the mass, the greater the gravitational power, the more the turbo effect emerges, and the more the atmosphere is inhaling, the more it swallows the surrounding hydrogen.
After a mixed battle until there was nothing left of the air herds, the battle ended and a large group of hydrogen gas formed.
So, the universe is now full of hydrogen gas.
The nature of the evolution of celestial bodies is a race against gravity.
These gases are brought together by pure gravity, the size of which is related to mass and distance.
This led to one result.
The more hydrogen the gas is swallowed up, the greater the mass;
The greater the mass, the greater the gravity; the greater the gravity, the more the gas mass is compressed;
The smaller the size, the closer the distance between the hydrogen molecules; the closer the distance, the greater the gravity.
As a result, the centre of the air mass has been condensed and under increasing pressure, which has been increasing to the point where two hydrogen atomic nucleus can be twisted together.
And it’s not known who made the rule that if the two hydrogen atomic nucleus are twisted together, they will release enormous energy, which is what humans call a fusion reaction, and that’s the principle of hydrogen bombs.
fusion glows and heats, and the light is the sun and starlight we see, and the heat swells the gas.
As the gas mass continues to compress, the hydrogen atoms involved in the fusion reaction increase, heat increases, and the power of gas inflates increases, increasing to balance with gravity, at a time when the structure of the air mass is stable and non-inflated and non-compressed.
It’s a ensemble of balance with unstoppable explosions: stars.
Like our sun.
There are also “quasi stars” that fail to refine, and gravitational forces can just collide a small core at the center, but the fusion response is not so intense as to burn the whole star, not as bright as a star.
This failed star is the brown dwarf.
There are more failures.
The previous period had escaped from the atmosphere to swallow up the surviving small air mass, which was not gravitational enough, and the centre of the air mass was unable to move the atomic nucleus, without a fusion reaction and without light heat, and finally became a gaseous planet.
For example, Jupiter, the largest planet in the solar system.
Stars rely on a fusion explosion to counterbalance power and gravity, and are destined to be futile.
Because the mass of the star remains the same, the gravity remains the same, but the fusion continues to consume energy.
It is not known who has made the rule that corroding atoms below iron will release energy and above iron atoms will consume energy together.
On the other hand, a nuclear division above iron would release energy and a nuclear division below iron would consume energy.
This is the concept of fusion and fission.
So, gravity twists the hydrogen of one proton into a helium of two protons, then turns it down to lithium (3 protons), carbon (6 protons), and then to iron (26 protons), and then screws it up, and it’s not sustainable, so it’s always gravitational.
And actually, stars don’t have a chance to twist hydrogen into iron.
Because the harder it gets, the harder it takes to screw two heliums together, the harder it takes to screw two hydrogens.
When most of the hydrogen inside the star is twisted into helium, the central pressure is not enough to shake it.
So the star loses the power of a fusion explosion, and then gravity continues to compress the size of the star until helium gathers.
Helium fusion, however, is not easy to do, and helium piles at the centre are first and foremost condensed and condensed.
It’s like a super high-pressure pot.
If the mass of the star is less than 0.8 times the mass of the sun and the internal pressure is not high enough, then the high-pressure pot will always be like this, commonly known as the white dwarf, because the composition is helium, also known as the helium dwarf.
If the mass of a star is above 2.0 times the mass of the sun and the internal pressure is high enough, then enough to twist the helium atom to the carbon atom before it becomes a high-pressure pot.
In this way, helium fusion replaces hydrogen fusion, with a constant supply of energy, and the gas can continue to counterbalance gravity, and the star will cease to contract and this round of helium flashes will escape.
The next round of carbon flashes will continue to be challenged a few years later, and failure will become a carbon-white dwarf, as is the case with the famous brick star.
If the star mass is between 0.8 and 2.0 times the mass of the sun, it’s trouble.
Before turning into a high-pressure pan, the internal pressure was not sufficient for helium fusion, and after becoming a high-pressure pan, the internal pressure continued to crush the high-pressure pan.
In the moment when the high-pressure pan was crushed, helium fusion was ignited, and this uncontrollable reaction was intense and brief, called “helium flashes”.
The background to the science fiction ” Vagrant Earth ” is the helium of the sun, which causes the Earth to wander.
These stars are out of the game, and the other stars continue to move up the next round.
At first, the star only reacts internally.
Because it’s the only place where gravity is big enough, but as it shrinks and gravity increases, the hydrogen in the outer layer will gradually become involved in fusion, and the internal helium fusion will start to be particularly intense, and the whole process will be extremely complex with dramatic changes in volume!
Such as a barrel of powder,
It’s:
The Red Star.
Big red stars rarely die naturally because of the complexity of their internal reaction, the new elements of fusion that you come to, and finally it’s hard to balance with gravity!
Sometimes, highs over the top, lift the table when they don’t agree.
That’s what’s famous: supernova explosions.
Under the terms of who knows, if there is enough energy to screw the atomic core, the local energy of such a violent explosion is very, very large, and it can rip out all kinds of large nuclears above iron, even the 92 proton freaks like uranium.
There’s an interesting thing here: without a supernova explosion, there’s probably only a few elements in the universe, such as helium helium carbon dioxide.
So-called elements are the convergence of basic particles in this battle.
Go on.
Through supernova explosions, stars throw out all these year-old homes and turn them into scattered cosmic dust, which, unlike at first light atoms, contains a variety of light and heavy elements.
The heavy elements can be combined to form solids, so the river is no longer the same.
Of course, a supernova explosion is not enough to produce sufficient dust, and it would be more appropriate at this time to describe it in terms of mass dead.
The dust has begun a new round of “crawling gangs” because it can form solids without gravitational pull alone.
In other words, it can exist in small blocks, so the dust gathers into a small solid ball.
This tiny solid ball is the source of most planets.
For example, our Earth.
Large red stars, which are often reborn with very high kernels, as well as red stars who have survived the explosion, will continue to refine in the next round.
The more hard it gets, the more helium goes, the more helium turns into carbon, and occasionally the oxygen, the radium or the magnesium, the more gravitational it gets.
Then, the era of fusion power and gravitational counterbalances, with no fusion energy, began again, and continued to compress, until the “electronics” had an opinion.
Electronics are also temperamental, and when they retire, they carry the burden of gravitational confrontation.
The pressure is called “electronic simplicity and pressure”.
Gravity, however, does not bring the electron together, so it is simple and presses as the compression increases and increases until it is balanced with gravity, at which point the atomic nucleus has been condensed and dense enough to reach 10 tons/cm3.
It compresses a star to the size of the Earth.
This is the white dwarf.
The small white dwarf has no fusion, and without external input of material or energy, it gradually cools off radiation, and the reactions have stopped and become a dead star.
This is the destiny of many stars: black dwarfs.
However, even if the first star in the universe eventually evolved into a white dwarf, as of today it has not completely cooled into a dead star, so black dwarf is only a concept.
The universe is still too young!
Large white dwarfs, gravity is so high, they ignore electronic simplicity and pressure, they push the electron directly into the core, and they form neutrons with protons, and the electron is gone.
Gravity continues to compress, placing the electrons into the atomic core and becoming neutrons.
At this point, the object is only 10 km in diameter, with a density of 1 billion tons/cm3 and is living off an atom nucleus that is super-high and large, and the neutrons are squeezed together in a close and seamless manner.
This is the neutron star.
The process by which a white dwarf becomes a neutron star is also very intense, usually when a supernova explodes without moving a violent object, and some neutron stars are formed by a white dwarf.
By the way, sometimes the celestial bodies are colliding, and the impact at this level is a perfect supernova explosion.
Many supernova explosions that have been observed by humans are the collision of neutron stars with white dwarfs.
Because the celestial bodies retain their original agular momentum in the dust congregate, almost all of them are rotating, and neutron stars are no exception.
Based on a constant agular kinetics, neutron stars become small and turn very quickly, and some neutron stars do not overlap with the rotation axis, as if the N and S polar positions of the magnets were constantly changing, sending very regular electromagnetic pulse signals.
Because it’s too regular to be considered an alien signal.
That’s the pulsar.
The little neutron star, which heats and sends signals, gradually exhausts its energy, and ultimately its destiny is the Black Dwarf Star.
The large neutron star, and the power of gravitational force, continued to compress, and finally, the theoretically uncompressable neutron was reduced to a “fiction point” and finally peaked into a known “black hole”.
What’s strange about a black hole is that once again, small, unincorporated basic particles have been compressed, as if a plastered bus had been crowded up 100 more people.
What are the particles? What is space?
Although the quantum field theory has a marginal interpretation of particles, the relativity responses to space are somewhat inadequate.
In relativism, it is argued that mass causes a curvature of space, and that black holes are so big and so big that they create a space convection that nothing can come out, including light.
But the introduction and discovery of gravitational waves has become a headache.
Gravity, like light, is also a wave and is transmitted to the outside at light speed.
Thus, the fact of an iron blow lay before us: no matter how gruesome a black hole may be, no matter what the space may be, no matter what it may be, it does not affect the external spread of gravity.
Further, in the current human perception, nothing can affect the spread of gravity.
It makes one wonder if gravity is spreading at a higher level? So that we can ignore anything in our three-dimensional world.
No wonder physics has been at the core of four fundamentals for so many years, and gravity alone cannot be unified.
That’s all about the black hole.
However, the black hole, the white hole, the wormhole, the three best blowjobs and the two others cannot be absent.
The white hole is a pure product of a mathematical equation.
Changed some of the values of the mathematical model of a black hole, and as a result the black hole went from “none” to “none” and then introduced the concept of a white hole.
The white hole is not only unfounded in observations, but also theoretically difficult to justify.
When you find the Jade Emperor, you can’t find the White Hole.
The concept of wormholes is much more solid.
In a broad relativism, space can be bent and gravity is large enough to fold space.
If a worm bites a hole out of the folding space, it can make a space leap, and then a wormhole is named.
It may have come to mind that, in the final analysis, the energy in the universe comes from the earliest hydrogen, the hydrogen atoms of which are fusion, and it is the energy that has been given to the evolution of the universe.
So, finally, there’s a small question:
And when all the hydrogen elements in the universe gather into iron, what’s next? Register number: YXA1bKrZbA8CxMjwK1ocPDPY
I don’t know.
Keep your eyes on the road.
