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Nuclear binding energy is what holds the nucleus of an atom together. When an atom is split, some of the binding energy is released. At the level of the atom, it is kinetic energy of the daughter atoms and particles. This is not different from their temperature, and so the nuclear binding energy is turned directly into heat on the fission of the atom. When we speak of nuclear energy, we are often speaking of nuclear power, referring to nuclear power plants. The above answer really works for them also, at the fundamental level.
The nuclear force is what binds the nucleons, which are protons and neutrons, together in the nucleus of an atom. The binding energy is the amount of energy needed to break the atom apart. The one is a force, and the other is a measurement.
Nuclear binding energy is the energy that holds nucleons (protons and neutrons) together in an atomic nucleus. It is derived from what is called mass deficit. Each nucleon in the atom gives up a tiny amount of its mass when the atom is created. This mass in converted into binding energy.
THE AMOUNT OF ENERGY STORED IN THE STRONG NUCLEAR FROCES OF THE NUCLEUS
The source of energy in a nuclear reactor is the release of binding energy, i.e. the binding energy that hold protons and neutrons together in the nucleus of the atom. Heavy nuclides, such as uranium, are split into lighter nuclides, such as cesium and barium (and many others, in a semi-random cross section). The binding energy required to hold the original uranium together is less than the daughter products and is released to the system in the form of heat and other radiation.
mass defect
the nuclear binding energy
Nuclear binding energy is what holds the nucleus of an atom together. When an atom is split, some of the binding energy is released. At the level of the atom, it is kinetic energy of the daughter atoms and particles. This is not different from their temperature, and so the nuclear binding energy is turned directly into heat on the fission of the atom. When we speak of nuclear energy, we are often speaking of nuclear power, referring to nuclear power plants. The above answer really works for them also, at the fundamental level.
E = MC2; energy is equal to a quantity of matter. When protons (and neutrons) combine in an atomic nucleus, the resultant mass is less than that of the individual particles. This is the mass defect, and the 'missing' mass is a result of the energy binding the particles together. The larger the mass defect for a particular atom (isotope), the larger the amount of nuclear binding energy.
Nuclear energy comes from the binding energy released when we change the state of atoms. Binding energy holds the universe together and it is present in every atom.
The energy stored in the nucleus of an atom is called atomic or nuclear energy. This energy is potential because it is kinetic.
Radiation
The nuclear force is what binds the nucleons, which are protons and neutrons, together in the nucleus of an atom. The binding energy is the amount of energy needed to break the atom apart. The one is a force, and the other is a measurement.
Nuclear binding energy is the energy that holds nucleons (protons and neutrons) together in an atomic nucleus. It is derived from what is called mass deficit. Each nucleon in the atom gives up a tiny amount of its mass when the atom is created. This mass in converted into binding energy.
Binding energy. and some is even stored in particles, such as the neutron which has a half-life of about ten minutes before it disintegrates with the release of energy.
A carbon 12 atom has a mass defect of .098931 u. This number, the mass defect, represents the binding energy of the nucleus of the nucleus of the atom, and how energy has to be used to split this nucleus.
THE AMOUNT OF ENERGY STORED IN THE STRONG NUCLEAR FROCES OF THE NUCLEUS