NCERT Exemplar solutions for Physics [English] Class 12 chapter 13 - Nuclei [Latest edition]

Suppose we consider a large number of containers each containing initially 10000 atoms of a radioactive material with a half life of 1 year. After 1 year ______.

The gravitational force between a H-atom and another particle of mass m will be given by Newton’s law: `F = G(M.m)/r^2`, where r is in km and ______.

When a nucleus in an atom undergoes a radioactive decay, the electronic energy levels of the atom ______.

M_x and M_y denote the atomic masses of the parent and the daughter nuclei respectively in a radioactive decay. The Q-value for a β^– decay is Q₁ and that for a β⁺ decay is Q₂. If m e denotes the mass of an electron, then which of the following statements is correct?

Tritium is an isotope of hydrogen whose nucleus Triton contains 2 neutrons and 1 proton. Free neutrons decay into `p + bare + barν`. If one of the neutrons in Triton decays, it would transform into He³ nucleus. This does not happen. This is because ______.

Heavy stable nucle have more neutrons than protons. This is because of the fact that ______.

In a nuclear reactor, moderators slow down the neutrons which come out in a fission process. The moderator used have light nuclei. Heavy nuclei will not serve the purpose because ______.

Fusion processes, like combining two deuterons to form a He nucleus are impossible at ordinary temperatures and pressure. The reasons for this can be traced to the fact ______.

1. nuclear forces have short range.
2. nuclei are positively charged.
3. the original nuclei must be completely ionized before fusion can take place.
4. the original nuclei must first break up before combining with each other.

Samples of two radioactive nuclides A and B are taken. λ_A and λ_B are the disintegration constants of A and B respectively. In which of the following cases, the two samples can simultaneously have the same decay rate at any time?

1. Initial rate of decay of A is twice the initial rate of decay of B and λ_A = λ_B.
2. Initial rate of decay of A is twice the initial rate of decay of B and λ_A > λ_B.
3. Initial rate of decay of B is twice the initial rate of decay of A and λ_A > λ_B.
4. Initial rate of decay of B is the same as the rate of decay of A at t = 2h and λ_B < λ_A.

The variation of decay rate of two radioactive samples A and B with time is shown in figure.

Which of the following statements are true?

1. Decay constant of A is greater than that of B, hence A always decays faster than B.
2. Decay constant of B is greater than that of A but its decay rate is always smaller than that of A.
3. Decay constant of A is greater than that of B but it does not always decay faster than B.
4. Decay constant of B is smaller than that of A but still its decay rate becomes equal to that of A at a later instant.

He₂³ and He₁³ nuclei have the same mass number. Do they have the same binding energy?

Draw a graph showing the variation of decay rate with number of active nuclei.

Which sample, A or B shown in figure has shorter mean-life?

Which one of the following cannot emit radiation and why? Excited nucleus, excited electron.

In pair annihilation, an electron and a positron destroy each other to produce gamma radiation. How is the momentum conserved?

Why do stable nuclei never have more protons than neutrons?

Consider a radioactive nucleus A which decays to a stable nucleus C through the following sequence:

A→B→C

Here B is an intermediate nuclei which is also radioactive. Considering that there are N₀ atoms of A initially, plot the graph showing the variation of number of atoms of A and B versus time.

A piece of wood from the ruins of an ancient building was found to have a ¹⁴C activity of 12 disintegrations per minute per gram of its carbon content. The ¹⁴C activity of the living wood is 16 disintegrations per minute per gram. How long ago did the tree, from which the wooden sample came, die? Given half-life of ¹⁴C is 5760 years.

Are the nucleons fundamental particles, or do they consist of still smaller parts? One way to find out is to probe a nucleon just as Rutherford probed an atom. What should be the kinetic energy of an electron for it to be able to probe a nucleon? Assume the diameter of a nucleon to be approximately 10^–15 m.

A nuclide 1 is said to be the mirror isobar of nuclide 2 if Z₁ = N₂ and Z₂ = N₁. (a) What nuclide is a mirror isobar of 11²³ Na? (b) Which nuclide out of the two mirror isobars have greater binding energy and why?

Sometimes a radioactive nucleus decays into a nucleus which itself is radioactive. An example is :

\[\ce{^38Sulphur ->[half-life][= 2.48h] ^{38}Cl ->[half-life][= 0.62h] ^38Air (stable)}\]

Assume that we start with 1000 ³⁸S nuclei at time t = 0. The number of ³⁸Cl is of count zero at t = 0 and will again be zero at t = ∞ . At what value of t, would the number of counts be a maximum?

Deuteron is a bound state of a neutron and a proton with a binding energy B = 2.2 MeV. A γ-ray of energy E is aimed at a deuteron nucleus to try to break it into a (neutron + proton) such that the n and p move in the direction of the incident γ-ray. If E = B, show that this cannot happen. Hence calculate how much bigger than B must E be for such a process to happen.

The deuteron is bound by nuclear forces just as H-atom is made up of p and e bound by electrostatic forces. If we consider the force between neutron and proton in deuteron as given in the form of a Coulomb potential but with an effective charge e′: F = `1/(4πε_0) e^('2)/r` estimate the value of (e’/e) given that the binding energy of a deuteron is 2.2 MeV.

Before the neutrino hypothesis, the beta decay process was throught to be the transition, `n -> p + vece`. If this was true, show that if the neutron was at rest, the proton and electron would emerge with fixed energies and calculate them. Experimentally, the electron energy was found to have a large range.

The activity R of an unknown radioactive nuclide is measured at hourly intervals. The results found are tabulated as follows:

1. Plot the graph of R versus t and calculate the half-life from the graph.
2. Plot the graph of ln `(R/R_0)` versus t and obtain the value of half-life from the graph.

Nuclei with magic no. of proton Z = 2, 8, 20, 28, 50, 52 and magic no. of neutrons N = 2, 8, 20, 28, 50, 82 and 126 are found to be very stable.

(i) Verify this by calculating the proton separation energy S_p for ¹²⁰Sn (Z = 50) and ¹²¹Sb = (Z = 51).

The proton separation energy for a nuclide is the minimum energy required to separate the least tightly bound proton from a nucleus of that nuclide. It is given by `S_P = (M_(z-1^' N) + M_H - M_(ZN))c^2`. 

Given ¹¹⁹In = 118.9058u, ¹²⁰Sn = 119.902199u, ¹²¹Sb = 120.903824u, ¹H = 1.0078252u.

(ii) What does the existance of magic number indicate?