It forms helium, and possibly heavier elements as well.
When matter is pulled into a protostar, it heats up and increases in density. This process leads to the formation of a protostar as gravitational forces pull matter towards the center, eventually igniting nuclear fusion and forming a stable star.
Nuclear fusion is a process that occurs at extremely high temperatures and involves the merging of atomic nuclei to release energy. It is not in a specific state of matter like gas, liquid, or solid, as it involves the transformation of matter at the atomic level.
During nuclear fusion, energy is released because some matter is converted into energy according to Einstein's famous equation E=mc^2. This means that a small amount of matter is converted into a large amount of energy, contributing to the immense power output of fusion reactions.
Stars produce energy through nuclear fusion. Earth is not massive enough for this to work. Nor does it have lots of hydrogen and helium, i.e. nuclear fuel, for that matter.
Actually, nuclear fusion is the process of combining atomic nuclei to form a heavier nucleus, releasing a large amount of energy in the process. It is the same process that powers the sun and other stars.
During nuclear fission and fusion, matter that seems to disappear is actually converted into energy.
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A nuclear reaction - either fusion or fission - is required to turn matter into energy.
In a nuclear reaction, matter is converted into energy.
The sun produces energy from matter in its core through the process of nuclear fusion. This involves the fusion of hydrogen atoms to form helium, releasing a large amount of energy in the form of light and heat.
When matter is pulled into a protostar, it heats up and increases in density. This process leads to the formation of a protostar as gravitational forces pull matter towards the center, eventually igniting nuclear fusion and forming a stable star.
Yes. In nuclear processes like fusion and fission, some matter is converted into energy.
The two main forces in a star are gravity and nuclear fusion. Gravity pulls matter inward, compressing it and creating the high pressure and temperature needed for nuclear fusion to occur. Nuclear fusion releases energy as light and heat, which counteracts the force of gravity trying to collapse the star.
The energy inside matter is called nuclear energy, which is stored in the nucleus of atoms. This energy can be released through processes such as nuclear fission or fusion.
Collapsing matter and gasses get denser and denser until nuclear fusion and fission start.