mgb_phys said:Yes you get helium, it's quite easy to do in large quantities if you have the correct equipement ( a star)
The isotopes of hydrogen are protium (the atom is comprised of one electron orbiting a single proton), deuterium (one electron orbiting a nucleus composed of one proton and one neutron), and tritium (one electron orbiting a nucleus composed of one proton and two neutrons). In all three isotopes, the single proton provides the positive charge which is equal in magnitude but opposite of the electron.Softballokie said:I am a freshman and in physical science but we have not yet come to fusion or anything like that. One day I just started to think.. what if you took an ordinary hydrogen atom (not an isotope.) and added 1 proton, 1 electron, and 2 neutrons in whatever way you could. Would you get helium, or just a very strange hydrogen atom, or what?
what if you took an ordinary hydrogen atom (not an isotope.) and added 1 proton, 1 electron, and 2 neutrons in whatever way you could
The process of converting hydrogen to helium is known as nuclear fusion, which occurs in the core of stars. This process involves the fusion of four hydrogen nuclei to produce one helium nucleus, along with a large amount of energy in the form of heat and light.
Converting hydrogen to helium is important because it is the main energy source for stars, including our sun. It also plays a crucial role in the formation of elements in the universe, as helium is the second most abundant element after hydrogen.
The conversion of hydrogen to helium is a key process in the life cycle of stars. As stars burn hydrogen to produce helium, they release a tremendous amount of energy, which allows them to shine and sustain themselves for millions or even billions of years. Eventually, when a star runs out of hydrogen, it will start to fuse helium into heavier elements, leading to its eventual death.
Currently, we do not have the technology to replicate the process of converting hydrogen to helium on Earth. The extreme conditions required for nuclear fusion, such as high temperatures and pressure, make it challenging to recreate on Earth. However, scientists are continuously working on developing fusion reactors that could potentially harness the energy from this process in the future.
The conversion of hydrogen to helium is essential for the balance and evolution of the universe. As stars convert hydrogen to helium, they release energy and produce heavier elements, which are then spread throughout the universe through processes like supernovae. This process is crucial for the formation of planets, including Earth, and the development of life as we know it.