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Question

Calculate the Q-value in the following decay:
19 8O19 9F+e+¯v.
These may look like long calculations; use the unit amu or u for the masses, and c2=931MeVu, and it will become much simpler.
Atomic masses:19 8O:19.003576 u; 19 9F:18.998403 u.

A
2.021 MeV
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B
3.754 MeV
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C
4.816 MeV
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D
5.165 MeV
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Solution

The correct option is C 4.816 MeV
The Q-value is the energy released in a radioactive process, and is equal to EQ=Δmc2, where Δm is the mass defect. Since the antineutrino ¯v has almost zero mass, we will compare masses of the nuclei and e only
19 8O19 9F+e+¯v.
What we are given are the atomic masses, which include all the electrons in the atoms present. In this calculation, we will denote atomic mass of X as m(X) and nuclear mass as mn(X), okay? The Q-value can be calculated as follows:
Q_value=Δmc2
=(Initial mass-energy)-(Final mass-energy)
=mn(19 8O)[mn(19 9F)+m(e)]c2
=mn(19 8O)mn(19 9F)[9×m(e)8×m(e)]c2
=[mn(19 8O)+8×m(e)][mn(19 9F)+9×m(e)]c2
=[m(19 8O)m(19 9F)]c2
Where m(19 8O) and m(19 9F) are the atomic masses, not nuclear masses anymore. Pretty smart, right? You don't have to derive this if you just remember that in a β decay, the Q-value is also equal to the difference in the atomic masses multiplied by c2.
Therefore, the Q-value of this process will be
=[m(19 8O)m(19 9F)]×c2
=[19.003576 u18.998403 u]×931 MeVu
=4.816MeV.

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