462 8 Nuclear Physics – II
8.3.10 Nuclear Reactions (General).........................
8.45 The given decay is
(^13) N→ (^13) C+β++ν+ 1 .2MeV (1)
MN−MC− 2 me= 1 .2MeV (2)
where masses are atomic andc= 1
For the reaction
p+^13 C→^13 N+n
Q=Mp+MC−MN−Mn
where the masses are nuclear.
Add and subtract 7meto get Q in atomic masses
Q=MH+MC−MN−Mn=−[(Mn−MH)+(MN−MC)]
Q=−[0. 78 + 1. 2 + 2 me]=−3MeV
where we have used (2) and the mass differenceMn−MH= 0 .78 MeV and
me= 0 .51 MeV
Ethreshold=|Q|
(
1 +
mp
mc)
= 3 ×
(
1 +
1
13
)
= 3 .23 MeV8.46 Given reaction is
p+^7 Li→^7 Be+n− 1 .62 MeV (1)
MLi+MP−MBe−Mn=− 1 .62 MeV (2)
where the masses are nuclear.
It follows that
MBe−MLi= 1. 62 + 938. 23 − 939. 52 = 0 .33 MeV
Add and subtract 4meto get theQmass difference of Be and Li
MBe−MLi−me= 0. 33
orMBe−MLi= 0. 33 +me= 0 .84 MeV
whereme= 0 .51 MeV. Thus the total energy released in the electron capture
e−+^7 Be→^7 Li+νis 0.84 MeV
This energy is shared between the neutrino and the recoil nucleus. Energy
and momentum conservation give
EN+Eυ= 0 .84 MeV (1)
Pυ^2 =E^2 υ=PN^2 = 2 MNEN (2)
UsingMN∼=7amu= 6520 .5 MeV, (1) and (2) can be solved to obtainEN=
7 .5 keV andEυ∼= 0 .84 MeV.8.47 The Q-value is− 1 .37 MeV. Minimum energy required is
Ea=|Q|(
1 +
ma
mx)
= 1. 37
(
1 +
1
24
)
= 1 .427 MeV