2 Marks Questions

Question 12 Marks

$a$. State Ampere's circuital law connecting the line integral of $B$ over a closed path to the net current crossing the area bounded by the path.
$b$. Use Ampere's law to derive the formula for the magnetic field due to an infinitely long straight current carrying wire.
$c$. Explain carefully why the derivation as in $(b)$ is not valid for magnetic field in a plane normal to a currentcarrying straight wire of finite length and passing through the midpoint of the axis.

Answer

$a$. Ampere's Circuital Law: It gives the relationship between the current and the magnetic field created by it.
This law says that the integral of magnetic field density $(B)$ along an imaginary closed path is equal to the product of current enclosed by the path and permeability of the medium.
$b$. Now, from Ampere's Circuital law, $\int B . dI =\mu_0 l$
$\Rightarrow \int B \cdot dl =\mu_0 l \ [$Since angle between $B$ and $ dl $ is zero$]$
$\Rightarrow B \int dl =\mu_0 l$
$\Rightarrow B .2 \pi r =\mu_0 l$ [Since the total length of dl is equal to circumference of the circle considered]
$\Rightarrow B =\frac{\mu_0 l}{2 \pi r}$ which is the required expression for magnetic field of induction due to a long straight current carrying wire.
$c$. A straight conductor of finite length cannot by itself form a complete, steady current circuit.
Additional conductors are necessary to close the circuit.
These will spoil the symmetry of the problem.
The difficulty disappears if the conductor is infinitely long.

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Question 22 Marks

Write the shortcomings of Rutherford atomic model. Explain how these were overcome by the postulates of Bohr's atomic model.

Answer

Shortcomings of Rutherford atomic model:
Rutherford proposed planetary model of an atom in which electrons revolve round the nucleus.
An electron revolving round the nucleus has an acceleration directed towards the nucleus.
Such accelerated electron must radiate electromagnetic radiation.
But, if an revolving electron radiates energy, the total energy of the system must decrease. In such situation, the electron must come closer to the nucleus and hit the nucleus. Also, the radiation spectrum of emitted electromagnetic waves should be continuous.
However, this does not happen in an atom. Atom is not unstable and the spectrum is not continuous. Rutherford atomic model cannot explain these two observations. These are the shortcomings of Rutherford Atomic Model.
To overcome this discrepancy, Neils Bohr put forward three postulates combining classical Physics and Planck's quantum hypothesis.
Bohr's 1st postulate provides stability to the atomic model.
Bohr's 2nd postulate provides justification that electrons may revolve in stationary orbit.
Bohr's 3rd postulate provides the explanation of line spectrum.

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Question 32 Marks

A galvanometer has a resistance of $8 \Omega$ . It gives a full scale deflection for a current of $10 mA$. It is to be converted into an ammeter of range $5 A$. The only shunt resistance available is of $0.02 \Omega$ , which is not suitable for this conversion. Find the value of resistance $R$ that must be connected in series with the galvanometer $($Fig.$)$ to get ammeter of desired range.

Answer

$P.D$. across the series combination of $G$ and $R = P.D$. across the shunt $S$
$ I _{ g }\left( R _{ g }+ R \right)=\left( I - I _{ g }\right) R$
$0.01(8+ R )=(5-0.01) \times 0.02=4.99 \times 0.02$
or $8+R=\frac{4.99 \times 0.02}{0.01}=9.98$
or $R =9.98-8=1.98 \Omega$

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Question 42 Marks

Explain the formation of the barrier potential in a p-n junction.

Answer

When the electrons and holes move towards each other leaving the charged ions negative on the p side and positive on the n side then an electric field is generated and the potential thus formed is called barrier potential.

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Question 52 Marks

The coercivity of a certain permanent magnet is $4.0 \times 10^4 Am ^{-1}$. This magnet is placed inside a solenoid 15 cm long and having 600 turns and a current is passed in the solenoid to demangnetise it completely. Find the current.

Answer

The coercivity of $4 \times 10^4 Am ^{-1}$ of the permanent magnet implies that a magnetic intensity $H =4 \times 10^4 Am ^{-1}$ is required to be applied in opposite direction to demagnetise the magnet.
Here $n =\frac{600}{15 m}=\frac{600}{15 \times 10^{-2} m}=4000 turns / m$
As $H = nl$
$\therefore$ Current, $I =\frac{H}{n}=\frac{4 \times 10^4}{4000}=10 A$

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Question 62 Marks

Arrange the following electromagnetic waves in the order of their increasing wavelength :
a. $\gamma$-rays
b. Microwaves
c. X-rays
d. Radio waves
How are infra-red waves produced? What role does infra-red radiation play in
i. maintaining the Earth's warmth and
ii. physical therapy?

Answer

In the order of increasing wavelength, the e.m. waves are
$\gamma$-rays, < X-rays < Microwaves < Radiowaves
Infrared rays are produced by hot bodies or by vibrations of atoms and molecules.
i. Infrared rays maintain earth's warmth through green house effect.
ii. Infrared lamps are used in physical therapy because of the heat produced by infrared rays.

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Physics 2 Marks Questions

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