5.23 times 10^-12 J APEX users !
7.56 x 10^13 J/mol
(Explanation): we will use the formula E=mc^2 for this problem. Substitute c, speed of light, with 3.0 x 10 ^ 8 and substitute m, the mass, with 5.81 x 10 ^ (-29). In your calculator, put (3.0 x 10 ^ 8) ^2 or 9.0 x 10 ^ 16 DIVIDED BY 5.81 x 10 ^ (-29) to get your answer
The energy is 5,22.10-12 J per atom.
The energy is 52,21.10e-17 J.
5.23x10-12J
The binding energy is the mass defect, times the square of the speed of light.The amount stated seems to be an awfully high mass defect, though.
Radiation
The mass defect represents the mass converted to binding energy
Knowledge about atomic nuclei has been used to produce energy.
With nuclear fission, a large atomic nucleus (such as a uranium nucleus) breaks apart into smaller nuclei, and energy is released. With nuclear fusion, small atomic nuclei (such as hydrogen) join to become larger nuclei, and energy is released. Fusion of hydrogen releases much more energy than any other type of either fusion or fission. Note that the dividing line between heavy nuclei and light nuclei is the iron nucleus, which is at the perfect point of nuclear stability, so that neither fusion nor fission of iron nuclei would release any energy.
7.56 x 10^13 J/mol
The binding energy is the mass defect, times the square of the speed of light.The amount stated seems to be an awfully high mass defect, though.
No. Binding energy differs from element to element,
For helium the binding energy per nucleon is 28.3/4 = 7.1 MeV. The helium nucleus has a high binding energy per nucleon and is more stable than some of the other nuclei close to it in the periodic table.
2.0 x 10^-2 kg/mol
The binding energy in atomic nuclei. This energy is transmitted by the strong force.
Radiation
The energy of nuclear power comes from the binding energy that holds an atomic nucleus together. A heavy nucleus, usually uranium-235, splits into two smaller nuclei and releases three neutrons. These new nuclei have less binding energy than the original, and the excess energy is released as heat.
No. Fission is the splitting of atomic nuclei, which releases binding energy. That is the nuclear force.
From the excess binding energy of the protons and neutrons in the atomic nuclei of certain isotopes.
The binding energy per nucleon varies in different nuclei, being a maximum in the region of iron and nickel, and getting progressively less as the heavier nuclei are approached, Therefore when a uranium nucleus splits into two nuclei of lighter elements, the total binding energy is increased, and this results in a loss of mass. The destroyed mass appears as energy, from the relation E = mc2. You can read more and see the binding energy graph in the link below. It is also evident why fusion of light nuclei like hydrogen also releases energy, as in this part of the graph binding energy increases as the nuclei get heavier.
A pairing energy is the extra binding energy associated with pairs of nucleons of the same kind - which results in nuclei which have odd numbers of protons or neutrons having a lower binding energy and being less stable than those with even numbers.