2 Marks Questions

Question 12 Marks

The decay constant of $\text{ }^{197}_{80}\text{Hg} ($electron capture to $\text{ }^{197}_{79}\text{Au})$ is $1.8 \times 10^{-4} S^{-1}.$

What is the half-life$?$
What is the average-life$?$
How much time will it take to convert $25\%$ of this isotope of mercury into gold$?$

Answer

$\text{t}_{\frac{1}{2}}=\frac{0.693}{\lambda}[\lambda\rightarrow$ Decay constant$]$

$\Rightarrow\text{t}_{\frac{1}{2}}=3820\text{sec}=64\text{min}$

Average life $=\frac{\text{t}_{\frac{1}{2}}}{0.693}=92\text{min}.$
$0.75=1\text{e}^{-\lambda\text{t}}\Rightarrow\text{In }0.75=-\lambda\text{t}$

$\Rightarrow\text{t}=\text{In}\frac{0.75}{-0.00018}=1598.23\text{sec.}$

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Question 22 Marks

Complete the following decay schemes.

$\text{ }^{226}_{88}\text{Ra}\rightarrow\alpha+$
$\text{ }^{19}_8\text{O}\rightarrow\text{ }^{19}_9\text{F}+$
$\text{ }^{25}_{13}\text{Al}\rightarrow\text{ }^{25}_{12}\text{Mg}+$

Answer

$\text{ }^{226}_{88}\text{Ra}\rightarrow\text{ }^4_2\alpha+\text{ }^{222}_{26}\text{Rn}$
$\text{ }^{19}_8\text{O}\rightarrow\text{ }^{19}_9\text{F}+\bar{\text{e}}+\bar{\text{v}}$
$\text{ }^{25}_{13}\text{Al}\rightarrow\text{ }^{25}_{12}\text{Mg}+\text{e}^++\text{v}$

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Question 32 Marks

A free neutron beta$-$decays to a proton with a half$-$life of $14$ minutes.

What is the decay constant?
Find the energy liberated in the process.

Answer

$\text{In}\rightarrow\text{P + e}^-$
We know : Half life $=\frac{0.6931}{\lambda} ($Where $\lambda =$ decay constant$).$
$\lambda=\frac{0.6931}{14\times60}=8.25\times10^{-4}\text{S} [$As half life $= 14min = 14 \times 60 \sec].$
Energy $= [M_n - (M_P + M_e)]u = [(M_{nu} - M_{pu}) - M_{pu}]c^2 = [0.00189u - 511KeV/c^2]$
$= [1293159 ev/c^2 - 511000ev/c^2]c^2 = 782159eV = 782Kev.$

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Question 42 Marks

Lithium $(Z = 3)$ has two stable isotopes $^6Li$ and $^7Li.$ When neutrons are bombarded on lithium sample, electrons and $\alpha-$particles are ejected. Write down the nuclear process taking place.

Answer

$\text{ }^6_3\text{Li + n}\rightarrow\text{ }^7_3\text{Li};\text{ }^7_3\text{Li + r}\rightarrow\text{ }^8_3\text{Li}$
$\text{ }^8_3\text{Li}\rightarrow\text{ }^8_4\text{Be + e}^-+\text{v}^-$
$\text{ }^8_4\text{Be}\rightarrow\text{ }^4_2\text{He}+\text{ }^4_2\text{He}$

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Question 52 Marks

In the decay $^{64}Cu \rightarrow ^{64}Ni + e^+ + v,$ the maximum kinetic energy carried by the positron is found to be $0.650\ MeV.$

What is the energy of the neutrino which was emitted together with a positron of kinetic energy $0.150\ MeV?$
What is the momentum of this neutrino in $kg-m/s?$

Use the formula applicable to a photon.

Answer

$^{64}Cu \rightarrow ^{64}Ni + e^+ + v,$ Emission of nutrino is along with a positron emission.

Energy of positron $= 0.650\ MeV.$

Energy of Nutrino $= 0.650 - KE$ of given position $= 0.650 - 0.150 = 0.5\ MeV = 500\ Kev.$

Momentum of Nutrino $=\frac{500\times1.6\times10^{-19}}{3\times10^8}\times10^3\text{J}=2.67\times10^{-22}\text{kg m/s}.$

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Question 62 Marks

Radioactive $^{131}$I has a half$-$life of $8.0$ days. A sample containing $^{131}$I has activity $20\mu\text{Ci}$ at $t = 0.$

What is its activity at $t = 4$ days?
What is its decay constant at $t = 4.0$ days?

Answer

$\text{t}_{\frac{1}{2}}=8.0\text{ days};\text{ A}_0=20\mu\text{Cl}$

$\text{t}=4.0\text{ dys};\lambda=\frac{0.693}{8}$

$\text{A = A}_{0}\text{e}^{-\lambda\text{t}}=20\times10^{-6}\times\text{e}^{\big(\frac{-0.693}{8}\big)\times4}$
$=1.41\times10^{-5}\text{Ci}=14\mu\text{Ci}$

$\lambda=\frac{0.693}{8\times24\times3600}=1.0026\times10^{-6}.$

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Question 72 Marks

The selling rate of a radioactive isotope is decided by its activity. What will be the second$-$hand rate of a one month old $\text{ }^{32}\text{P}\big(\text{t}_{\frac{1}{2}}=14.3\text{days}\big)$ source if it was originally purchased for $800$ rupees?

Answer

$\text{t}_{\frac{1}2{}}=14.3\text{ days};\text{ t}=30\text{ days}=1\text{ month}$
As, the selling rate is decided by the activity, hence $A_0 = 800$ disintegration/sec.
We know, $\text{A = A}_0\text{e}^{-\lambda\text{t}}$ $\Big[\lambda=\frac{0.693}{14.3}\Big]$
$\text{A}=800 \times 0.233669 = 186.935 = 187\text{ rupees.}$

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Question 82 Marks

$^{57}Co$ decays to $^{57}Fe$ by $\beta^+-\text{ emission.}$- emission. The resulting $^{57}Fe$ is in its excited state and comes to the ground state by emitting $\gamma-\text{rays}.$ The half-life of $\beta^+-\text{decay}$ is $270$ days and that of the $\gamma-\text{emissions}$ is $10^{-8} s.$ A sample of $^{57}Co$ gives $5.0 \times 10^9$ gamma rays per second. How much time will elapse before the emission rate of gamma rays drops to $2.5 \times 10^9$ per second$?$

Answer

According to the question, the emission rate of $\gamma-\text{rays}$ will drop to half when the $\beta^+\text{decays}$ to half of its original amount. And for this the sample would take $270$ days.
$\therefore$ The required time is $270$ days.

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Question 92 Marks

Calculate the mass of an $\alpha-$particle. Its binding energy is $28.2MeV.$

Answer

Let the mass of $'\alpha'$ particle be $xu.$
$'\alpha'$ particle contains $2$ protons and $2$ neutrons.
$\therefore$ Binding energy $= (2 \times 1.007825u \times 1 \times 1.00866u - xu)C^2 = 28.2MeV ($given$).$
$\therefore x = 4.0016u.$

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Question 102 Marks

When a boron nucleus $\big(\text{ }^{10}_5\text{B}\big)$ is bombarded by a neutron, an $\alpha$-particle is emitted. Which nucleus will be formed as a result?

Answer

It is given that when a boron nucleus$\big(\text{ }^{10}_5\text{B}\big)$ is bombarded by a neutron, an $\alpha$-particle is emitted.
Let X nucleus be formed as a result of the bombardment.
According to the charge and mass conservation,
$ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \text{ }^{10}_5\text{B}+^1_0\text{n}\rightarrow\text{X}+^4_2\text{He}\\\text{Charge}: \ \ 5 \ \ \ \ \ \ \ \ \ 0 \ \ \ \ \ \ \ 3 \ \ \ \ \ \ \ \ \ 2\\\text{Mass}:\ \ \ \ 10 \ \ \ \ \ \ \ \ \ 1 \ \ \ \ \ \ \ 7 \ \ \ \ \ \ \ \ \ 4$
The mass number of X should be 7 and its atomic number should be 3.
$\therefore\text{X}=^7_3\text{Li}$

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Question 112 Marks

The masses of $^{11}C$ and $^{11}B$ are respectively $11.0114u$ and $11.0093u.$ Find the maximum energy a positron can have in the $\beta^+$-decay of $^{11}C$ to $^{11}B.$

Answer

Given:
Mass of $^{11}C, m(^{11}C) = 11.0114u$
Mass of $^{11}B, m(^{11}B) = 11.0093u$
Energy liberated in the $\beta^+$ decay $(Q)$ is given by
$Q = [m(^{11}C) - m(^{11}B) - 2me]c^2$
$= (11.0114u - 11.0093u - 2 \times 0.0005486u)c^2$
$= 0.0010028 \times 931\ MeV$
$= 0.9336MeV = 933.6\ keV$
For maximum $KE$ of the positron, energy of neutrino can be taken as zero.
$\therefore$ Maximum $KE$ of the positron $= 933.6\ keV$

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