I believe that yes, it should occur - assuming any atoms are left. Please note that in the case of a neutron star, most of the atoms are crushed out of existence - i.e., there are no more atoms left, except a few in the outermost layers. Similarly, in a black hole, no atoms will be left.
A star dies when it runs out of fuel to sustain nuclear fusion in its core. This fuel is mainly hydrogen, which gets converted into helium through nuclear fusion. Once the star runs out of hydrogen, it will expand and eventually collapse, leading to its death in a supernova explosion.
Nuclear fusion is the process by which stars generate energy by fusing lighter elements into heavier ones. In the life cycle of a star, nuclear fusion occurs in the core and provides the energy necessary to counteract gravitational forces and maintain the star's equilibrium. As a star exhausts its nuclear fuel, it may undergo different stages of fusion, eventually leading to its death.
The core of an average-sized star near death is typically composed of a dense and hot ball of helium and heavier elements. As the star exhausts its nuclear fuel, it collapses and heats up, causing the core to contract and trigger further nuclear reactions. This process eventually leads to the star's core running out of fuel and collapsing further, resulting in a supernova explosion or the formation of a white dwarf, neutron star, or black hole.
During the supergiant stage of a massive star's life, elements heavier than iron are formed through the process of nucleosynthesis, primarily during supernova explosions. This includes elements like nickel, copper, zinc, and various heavier elements such as gold and uranium, which are produced through rapid neutron capture processes known as the r-process. These heavy elements are ejected into space during the star's explosive death, enriching the interstellar medium and contributing to the formation of new stars and planets.
Yes, supernovas are responsible for creating and dispersing elements critical for life, such as carbon, oxygen, and iron, into the universe. These elements are formed in the extreme conditions present during the explosive death of massive stars and are then incorporated into new stars, planets, and eventually life forms.
A star dies when it runs out of fuel to sustain nuclear fusion in its core. This fuel is mainly hydrogen, which gets converted into helium through nuclear fusion. Once the star runs out of hydrogen, it will expand and eventually collapse, leading to its death in a supernova explosion.
Nuclear Death ended in 2000.
Nuclear Death was created in 1986.
Heavier elements in the universe were formed through processes like nuclear fusion in the cores of stars, supernova explosions, and collisions between neutron stars. These events create the conditions necessary for the fusion of lighter elements into heavier ones.
Nuclear fusion is the process by which stars generate energy by fusing lighter elements into heavier ones. In the life cycle of a star, nuclear fusion occurs in the core and provides the energy necessary to counteract gravitational forces and maintain the star's equilibrium. As a star exhausts its nuclear fuel, it may undergo different stages of fusion, eventually leading to its death.
the fuel remains active for thousands of years and is very deadly to humans causing certain death
What an interesting question. The answer is however complex.It is possible to make small amounts of some radioactive elements or radioactive isotopes of some elements in a laboratory (usually involving a nuclear pile or an accelerator). For instance the element Plutonium is made this way.(Other radioactive elements are produced naturally by the radioactive decay of heavier radioactive elements)However, making a radioactive element or isotope from scratch requires the application of an enormous amount of energy. The place where all elements heavier than the element Iron (Fe - Atomic number 26) are made is in stellar explosions, the death of stars 8 or more times more massive than our Sun, called "supernovas".It is in supernova explosions that the radioactive elements are made.
The core of an average-sized star near death is typically composed of a dense and hot ball of helium and heavier elements. As the star exhausts its nuclear fuel, it collapses and heats up, causing the core to contract and trigger further nuclear reactions. This process eventually leads to the star's core running out of fuel and collapsing further, resulting in a supernova explosion or the formation of a white dwarf, neutron star, or black hole.
effects of nuclear power: nuclear fission or fussion emitts harmfull radiations like beta rays gamma rays uv rays these rays causes skin cancer many skin diseases and longer exposer may causes death. it creats global warming because of the emitted radiations.
No, Uranium is a rare-ish element whose radioactive isotope is often used in nuclear reactors. ingestion of radioactive elements can result in death
In my opinion, Nile.
When the star runs out of fuel. Most stars burn (fuse, actually) hydrogen. When this runs out, what happens next depends on the mass of the star... heavier stars can fuse heavier elements for a short time, but lower mass stars simply collapse into white dwarfs.