The mass defect represents the mass converted to binding energy
5.23 10-12 j
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2.0 x 10^-2 kg/mol
2.0 10-2 kg/mol
binding energy expressed in mass units is mass defect .mass defect expressed in energy units is binding energy
binding energy is a energy that help to bind molecules each other
5.23 x 10-12 J
mass defect
binding energy is the energy equivalent to the missing mass in the nucleus
Mass is converted to the energy binding a nucleus together
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m=0.009106u
mass defect
Nuclear binding energy is the energy required to hold the nucleus together. The mass defect is the difference between the mass of a nucleus and the sum of the masses of its individual protons and neutrons. The mass defect is converted into nuclear binding energy according to Einstein's famous equation, E=mc^2, where E is the energy, m is the mass defect, and c is the speed of light.
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.
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.
The greater the binding energy the more stable the nucleus is.
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 or nucleus binding energy are one and the same. IT is the force which is holding the nucleons together (protons and neutrons). Higher the binding energy , higher the stability of the nucleus.
binding energy is the energy equivalent to the missing mass in the nucleus
Mass is converted to the energy binding a nucleus together
The greater the nuclear binding energy, the more stable the nucleus. Even numbers of nucleons also make the nucleus more stable.
No. The maxiumum binding energy is of Iron nucleus (A=56) after which the binding energy starts decreasing.
THE AMOUNT OF ENERGY STORED IN THE STRONG NUCLEAR FROCES OF THE NUCLEUS