This cookie is installed by Google Analytics. The cookies store information anonymously and assign a randomly generated number to identify unique visitors. The cookie is used to calculate visitor, session, campaign data and keep track of site usage for the site's analytics report. This is used to present users with ads that are relevant to them according to the user profile. Used by Google DoubleClick and stores information about how the user uses the website and any other advertisement before visiting the website. These cookies help provide information on metrics, the number of visitors, the bounce rate, the source of traffic, etc. While different, the two processes have an important role in the past, present and future of energy creation.Analytics cookies are used to understand how visitors interact with the website. Fission is the splitting of a heavy, unstable nucleus into two lighter nuclei, and fusion is the process where two light nuclei combine together releasing vast amounts of energy. However, research continues into ways to better harness the power of fusion, but research is in experimental stages, as scientists continue to work on controlling nuclear fusion in an effort to make a fusion reactor to produce electricity.īoth fission and fusion are nuclear reactions that produce energy, but the processes are very different. Fusion reactions are not easily controlled, and it is expensive to create the needed conditions for a fusion reaction. These benefits are countered by the difficulty in harnessing fusion. Fusion offers an appealing opportunity, since fusion creates less radioactive material than fission and has a nearly unlimited fuel supply. Some scientists believe there are opportunities to do so. While fission is used in nuclear power reactors since it can be controlled, fusion is not yet utilized to produce power. The high-speed neutrons that are ejected become projectiles that initiate other fission reactions, or chain reactions. This resulting energy is then used to heat water in nuclear reactors and ultimately produces electricity. This splits the target nucleus and breaks it down into two smaller isotopes (the fission products), three high-speed neutrons, and a large amount of energy. During the process, a neutron is accelerated and strikes the target nucleus, which in the majority of nuclear power reactors today is Uranium-235. These neutrons are accelerated and then slammed into the unstable isotope, causing it to fission, or break into smaller particles. Fission takes place when a large, somewhatunstable isotope (atoms with the same number of protons but different number of neutrons) is bombarded by high-speed particles, usually neutrons.
Just as cell’s divide, in fission an atom splits into smaller particles. Both fission and fusion alter atoms to create energy, but what is the difference between the two?įission, a term coined by scientists LIse Meitner and Otto Frisch, is named after the term “binary fission” in biology to describe cell division. The foundation of nuclear energy is harnessing the power of atoms by splitting apart, a process called fission, or combining them, called fusion. Inside the sun, fusion reactions take place at very high temperatures and enormous gravitational pressures. Look up during the day to see one of the most powerful examples of a nuclear reactor: the sun.
Inside the sun, fusion reactions take place at very high temperatures and enormous gravitational pressures