Chapter 20, Problem 71AE

Interpretation Introduction

Interpretation:The following table needs to be completed with the particle produced in reaction.

Initial nuclide	Product nuclide	Particle produced
${}_{94}^{239}Pu$	${}_{92}^{235}U$
${}_{82}^{214}Pb$	${}_{83}^{214}Bi$
${}_{27}^{60}Co$	${}_{99}^{60}Ni$
${}_{43}^{99}Tc$	${}_{44}^{99}Ru$
${}_{93}^{239}Np$	${}_{94}^{239}Pu$

Concept introduction:

The fusion reaction or nuclear reaction can be defined as the reaction which follows the combination of two or more atomic nuclei and this result in the formation of one or more different atomic nuclei and subatomic particle. There is difference of the mass between the reactant and product which results the release or absorption of energy.

Answer to Problem 71AE

Initial nuclide	Product nuclide	Particle produced
${}_{94}^{239}Pu$	${}_{92}^{235}U$	${}_2^{4}He$
${}_{82}^{214}Pb$	${}_{83}^{214}Bi$	${}_{-1}^{0}e$
${}_{27}^{60}Co$	${}_{99}^{60}Ni$	${}_{-1}^{0}e$
${}_{43}^{99}Tc$	${}_{44}^{99}Ru$	${}_{-1}^{0}e$
${}_{93}^{239}Np$	${}_{94}^{239}Pu$	${}_{-1}^{0}e$

Explanation of Solution

The unstable radioactive nucleus will undergo disintegration and will also emit particle such as alpha particle $\alpha {\text{ or }}_2^{4}He$ , beta particle $\beta {\text{ or }}_{-1}^{0}e$ and gamma particle $\gamma$ for the stable configuration.

The conservation of mass and atomic number of any nuclear reaction can be given by the summation of summation of mass number of reactants which is equal to the summation of the mass number of products.

The nuclear reaction of $Pu$ can be given as −

  ${}_{94}^{239}Pu{\to }_{92}^{235}U{+}_2^{4}He$

Now, from the above reaction, the particle produced = ${}_2^{4}He$

The nuclear reaction of $Pb$ can be given as −

  ${}_{82}^{214}Pb{\to }_{83}^{214}Bi{+}_{-1}^{0}e$

Now, from the above reaction, the particle produced = ${}_{-1}^{0}e$

The nuclear reaction of $Co$ can be given as −

  ${}_{27}^{60}Co{\to }_{28}^{68}Bi{+}_{-1}^{0}e$

Now, from the above reaction, the particle produced = ${}_{-1}^{0}e$

The nuclear reaction of $Tc$ can be given as −

  ${}_{43}^{99}Tc{\to }_{44}^{99}Ru{+}_{-1}^{0}e$

Now, from the above reaction, the particle produced = ${}_{-1}^{0}e$

The nuclear reaction of $Tc$ can be given as −

  ${}_{93}^{239}Np{\to }_{94}^{239}Pu{+}_{-1}^{0}e$

Now, from the above reaction, the particle produced = ${}_{-1}^{0}e$

Now, the table can be given as −

Initial nuclide	Product nuclide	Particle produced
${}_{94}^{239}Pu$	${}_{92}^{235}U$	${}_2^{4}He$
${}_{82}^{214}Pb$	${}_{83}^{214}Bi$	${}_{-1}^{0}e$
${}_{27}^{60}Co$	${}_{99}^{60}Ni$	${}_{-1}^{0}e$
${}_{43}^{99}Tc$	${}_{44}^{99}Ru$	${}_{-1}^{0}e$
${}_{93}^{239}Np$	${}_{94}^{239}Pu$	${}_{-1}^{0}e$

Conclusion

It can concluded that the complete table of the particle produced in reaction is given as −

Initial nuclide	Product nuclide	Particle produced
${}_{94}^{239}Pu$	${}_{92}^{235}U$	${}_2^{4}He$
${}_{82}^{214}Pb$	${}_{83}^{214}Bi$	${}_{-1}^{0}e$
${}_{27}^{60}Co$	${}_{99}^{60}Ni$	${}_{-1}^{0}e$
${}_{43}^{99}Tc$	${}_{44}^{99}Ru$	${}_{-1}^{0}e$
${}_{93}^{239}Np$	${}_{94}^{239}Pu$	${}_{-1}^{0}e$