Energy released in fusion of `1 kg` of deuterium nuclei.

The energy released during the fussion of 1 kg uranium is

The amount of energy released in burning 1 kg of coal is

Calculate and compare the energy released by (a) fusion of 1.0kg of hydrogen deep within the sun, and (b) the fission of 1.0kg of U^(235) in a fission reactor.

Calculate the energy released when a single helium nucleus is formed by the fusion of two deuterium nuclei Given m(._(1)H^(2))=2.01478 amu and m(._(2)He^(4))=4.00388 amu.

The energy released during the fission of 1kg of U^(235) is a E_1 and that product during the fusion of 1 kg of hydrogen is E_2 . If energy released per fission of Uranium - 235 is 200 MeV and that per fusion of hydrogen is 24.7 MeV , then the ratio E_2/E_1 is

If the energy released in the fission of the nucleus is 200 MeV . Then the number of nuclei required per second in a power plant of 6 kW will be.

The atomic masses of deuteron, helium, neutron are 2.014 amu, 3.017 amu and 1.008 amu respectively. On fusion of 0.5 kg of deuterium, ""_(1)H^(2) + ""_(1)H^(2) to ""_(2)He^(3) + ""_(0)n^(1) , the total energy released is

Assertion : In a nuclear process energy is released if total binding energy of daughter nuclei is more than the total binding energy of parent nuclei. Reason: If energy is released then total mass of daughter nuclei is less than the total mass of parent nuclei.