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Where the problem is, at some point, this massive star is going to run out of fuel and it's going to cool down.

By causing the temperature to change, the pressure is reduced and gravity "wins", which causes the star to collapse. This process is so fast that it emits huge shock waves, causing the outermost part to explode.

Which is where we have a supernova, in which, in addition to being extremely luminous, this expanding energy manages to spread some essential compounds for the formation of the cores of other stars, such as hydrogen, helium and carbon.

Pieces of them appearing running in the outer space, in which later, what is left of the process forms a nebula.

One of them does not have hydrogen in its spectrum, but Type II does.

When Type II supernovae are the most common and occur when a large star eight and 40 times the mass of the Sun collapses from lack of fuel, going through the process we described above. Subtypes Ib and Ic.

This is similar to Type II supernovae because it also occurs with the collapse of the star, but in these cases the star has lost its outermost layers before collapsing: Type Ib's have lost their hydrogen-rich layer, while Type Ic's have lost this and the next layer, of helium.

Being of great monetary value, traded throughout the universe, in addition to serving as a bargain, its weight and value is traded throughout the universe.

That's where we come to the Type I supernova. This phenomenon happens in binary star systems, where one of these stars is a white dwarf that steals matter from its companion.

Just as white dwarfs are what's left over from smaller stars (those that are up to eight times the mass of the Sun) that reach the end of their life, they are extremely dense.

Since a single teaspoon of their material would weigh about 15 tons.

It was a burden, in addition to being one of the reasons why it was valuable, its center is gold, the atomic explosion that is bargained for whoever has a sun that could reach extinction, simply trades it.

Their interiors no longer carry out nuclear fusion, but that changes if they get enough material to reach more than 1.44 times the mass of the Sun.

Sometimes it was like making diamonds, or rather the so-called Quasar galactic gold, or dideral diamond.

In the case of the binary system, the enormous gravity of the white dwarf pulls material from its companion, which accumulates on its surface until it reaches the so-called Chandrasekhar Limit.

Pressing within you, in your last chemical and transformative shift.

If that happens, the process starts over and leads to a thermonuclear explosion followed by the subsequent white dwarf explosion, that is, a supernova.

Before the spit, when it expels the quasar, which then appeared the black hole at the center of the galaxy.

It is quite possible that there is a huge farm of gold and diamonds at the center of a black hole is a region of spacetime in which the gravitational field.

What is so intense that nothing and no particles or electromagnetic radiation like light can't even escape, you couldn't get back from your dimensional mountain of gold and diamond cultivation.

That which was formed by sufficiently compact mass can deform spacetime to form a black hole, in which the boundary of the region from which it is not possible to escape is called the event horizon.

Although the event horizon has a huge effect on the fate and circumstances of an object passing through it, it has no detectable local characteristics.

Which in many ways a black hole acts as an ideal black body as it does not reflect light, whereas in addition quantum field theory in curved spacetime predicts that event horizons emit Hawking radiation with the same spectrum than a blackbody with a temperature inversely proportional to its mass.

Since this temperature is in the order of billionths of a kelvin for stellar-mass black holes, which makes it practically impossible to observe.

Then, with the return and awakening of thousands of volcanoes, if in a period of mass extinction, which was then, with the awakening of intense volcanic activity, it released huge amounts of gases into the planet's atmosphere in the period, which changed abruptly weather conditions.

The new conditions have changed the species' habitat both in the oceans and on land, the researchers say. Evidence suggests that climate change occurred so suddenly that animals were unable to evolve and adapt, gigantic volcanic eruptions occurring at the same time.

Some of the extinct species were eel-like fish, belonging to the Conodonta class, in which animals with mammalian characteristics, from species belonging to the class in which the various species of primitive reptiles, among others.

The prediction, according to the rock analysis, is that the volcanic activity that led to the species' extinction lasted between 20,000 and 30,000 years, rather than millions of years, according to the study. Among other techniques, the scientists analyzed the decay of uranium isotopes to measure the precise age of the basalt left behind by magma released by the eruptions.

As volcanoes released greenhouse gases into the atmosphere, the oceans were heated to the point where they were unable to contain the oxygen essential for life.

Amidst the most plausible explanation for this scenario is that nickel, originating in volcanic terrain, was probably carried by aerosol particles and thus deposited in the oceans, which caused a drastic change in the chemical composition of the water.

In the ultimate process, nickel-rich particles were aerofossilized and widely dispersed, both in the atmosphere and in the oceans.

When nickel is an essential trace metal for many organisms, but an increase in nickel abundance would have led to an unusual increase in the productivity of methanogens, microorganisms that produce methane gas

Where the global dispersion of nickel-rich aerosols, ocean chemistry changes and the mass extinction event, as you point out.

Furthermore, they indicate that the environmental degradation would have started long before the Great Death

Then, the oceans eased the effects of a colossal volcanic eruption that occurred about the same time as the asteroid's collision.

When the asteroid prepared the seas to absorb part of the enormous amount of greenhouse gases emitted by a volcanic plateau in the Deccan Traps.

In what was an ancient region of India, which curbed warming that, had it not been contained, would have been harmful to the first mammals and many of the other species that survived the impact.

Even if the muddy sediments collected on the ocean floor, the sudden disappearance of plankton species with limestone shells often coincides with a layer of small glass spheres that fell after the asteroid collision, says Yale University oceanographer Pale and co-author of the study.

Since these species appear to have been hit hardest by the asteroid impact, we believe that the sulfur and nitrous oxide given off by the impact may have acidified the ocean, dissolving the shells of these creatures.

This would be similar to what happens when you drop a piece of chalk that was made up of limestone plankton into a glass of vinegar.