CBSE 2025, Set 3 Solutions
CBSE Physics (2025)

A double-convex lens, made of glass of refractive index $1.5$, has focal length $10\text{ cm}$. The radius of curvature of its each face, is:

A small bulb is placed at the bottom of a tank containing a transparent liquid (refractive index $n$) to a depth $H$. The radius of the circular area of the surface of liquid, through which light from the bulb can emerge out, is $R$. Then $(\frac{R}{H})$ is:

The angle of minimum deviation for a ray of light incident on a thin prism, made of crown glass ($n=1.52$) is $D_m$. If the prism was made of dense flint glass ($n=1.62$) instead of crown glass, the angle of minimum deviation will :

A parallel beam of light is incident on a face of a prism with refracting angle $60^\circ$. The angle of minimum deviation is found to be $30^\circ$. The refractive index of the material of the prism is close to:

An object is placed in front of a convex spherical glass surface ($n=1.5$ and radius of curvature $R$) at a distance of $4R$ from it. As the object is moved slowly close to the surface, the image formed is:

(a) (i) Explain with the help of a labelled ray diagram the formation of final image by an astronomical telescope at infinity. Write the expression for its magnifying power.\n(ii) The total magnification produced by a compound microscope is 20. The magnification produced by the eyepiece is 5. When the microscope is focussed on a certain object, the distance between the objective and eyepiece is observed to be $14\text{ cm}$. Calculate the focal lengths of the objective and the eyepiece. (Given that the least distance of distinct vision = $25\text{ cm}$)

Assertion (A): The minimum negative potential applied to the anode in a photoelectric experiment at which photoelectric current becomes zero, is called cut-off voltage.\n\nReason (R): The threshold frequency for a metal is the minimum frequency of incident radiation below which emission of photoelectrons does not take place.

Assertion (A): A ray of light is incident normally on the face of a prism. The emergent ray will graze along the opposite face of the prism when the critical angle at glass-air interface is equal to the angle of the prism.\n\nReason (R): The refractive index of a prism depends on angle of the prism.

Assertion (A): EM waves do not require a medium for their propagation.\n\nReason (R): EM waves are transverse waves.

An ac source of voltage $V = V_0 \sin \omega t$ is connected to a circuit element X. It is observed that the current flowing through X varies as $I = I_0 \sin(\omega t - \frac{\pi}{2})$.\n(a) Identify the element X and write the expression for its reactance.\n(b) Plot a graph to show the variation of reactance of the element with the frequency of the applied voltage.\n(c) Draw plots showing the variation of voltage and current with time over one cycle of applied ac.

The dimensions of 'self-inductance' are:

A rectangular coil of area $A$ is kept in a uniform magnetic field $\vec{B}$ such that the plane of the coil makes an angle $\alpha$ with $\vec{B}$. The magnetic flux linked with the coil is:

(a) (i) Write Biot-Savart's law in vector form.\n(ii) Two identical circular coils A and B, each of radius R, carrying currents $I$ and $\sqrt{3}I$ respectively, are placed concentrically in XY and YZ planes respectively. Find the magnitude and direction of the net magnetic field at their common centre.

(a) (i) With the help of a labelled diagram, explain the principle of working of a moving coil galvanometer. Write the purpose of using (1) radial magnetic field, and (2) soft iron core, in it.\n(ii) Define current sensitivity of a galvanometer. "Increasing the current sensitivity may not necessarily increase the voltage sensitivity." Give reason.

Assertion (A): A charged particle is moving with velocity $v$ in $x\text{-}y$ plane, making an angle $\theta$ ($0 < \theta < \frac{\pi}{2}$) with x-axis. If a uniform magnetic field $\vec{B}$ is applied in the region, along y-axis, the particle will move in a helical path with its axis parallel to x-axis.\n\nReason (R): The direction of the magnetic force acting on a charged particle moving in a magnetic field is along the velocity of the particle.

A rectangular loop of sides $l$ and $b$ carries a current $I$ clockwise. Write the magnetic moment $\vec{m}$ of the loop and show its direction in a diagram.\n(ii) The loop is placed in a uniform magnetic field $\vec{B}$ and is free to rotate about an axis which is perpendicular to $\vec{B}$. Prove that the loop experiences no net force, but a torque $\vec{\tau} = \vec{m} \times \vec{B}$.

A soft iron rod X is allowed to fall on the two poles of a U shaped permanent magnet as shown in figure. A coil is wrapped over one arm of the U shaped magnet.

During fall of the rod, the current in the coil will be:

In the circuit shown, the charge on the left plate of $20 \mu\text{F}$ capacitor is $50 \mu\text{C}$. The charge on the right plate of the $12 \mu\text{F}$ capacitor is :\n\n

Germanium crystal is doped at room temperature with a minute quantity of boron. The charge carriers in the doped semiconductors will be :

A steady current $I$ is passed through a conductor at room temperature for time $t$. It is observed that its temperature rises by $0.5^\circ\text{C}$. If $2I$ current is passed through the conductor (at room temperature) for the same duration, the rise in its temperature will be approximately:

Isotones are the nuclides having :

A metal rod of length $50\text{ cm}$ is held vertically and moved with a velocity of $10\text{ m/s}$ towards east. The horizontal component of the Earth's magnetic field at the place is $0.4\text{ G}$. The emf induced across the ends of the rod is:

The frequency of a photon of energy $1.326\text{ eV}$ is:

An alternating current is given by $I = I_0 \cos (100\pi t)$. The least time the current takes to decrease from its maximum value to zero will be:

The minimum energy required to free the electron from the ground state of the hydrogen atom is:

A capacitor and an inductor are connected in series across an ac source of voltage of variable frequency. The frequency is increased continuously. The nature of the circuit before and after the resonance will be :

A p-n junction diode is forward biased. As a result,

Calculate the value of the current passing through the battery in the given circuit diagram.\n\n

In a Young's double-slit experiment, the intensity at the central maximum in the interference pattern on the screen is $I_0$. Find the intensity at a point on the screen where the path difference between the interfering waves is $\frac{\lambda}{6}$.

Define the 'distance of closest approach'. An $\alpha$-particle of kinetic energy $K$ is bombarded on a thin gold foil. Derive an expression for the 'distance of closest approach'.

Using the mirror equation and the formula of magnification, deduce that "the virtual image produced by a convex mirror is always diminished in size and is located between the pole and the focus."

A convex lens of focal length $10\text{ cm}$, a concave lens of focal length $15\text{ cm}$ and a third lens of unknown focal length are placed coaxially in contact. If the focal length of the combination is $+12\text{ cm}$, find the nature and focal length of the third lens, if all lenses are thin. Will the answer change if the lenses were thick?

Draw energy band diagrams of n-type and p-type semiconductors at temperature $T > 0\text{ K}$. Show the donor/acceptor energy levels with the order of difference of their energies from the bands.

Explain the process of formation of 'depletion layer' and 'potential barrier' in a p-n junction region of a diode, with the help of a suitable diagram. Which feature of junction diode makes it suitable for its use as a rectifier?

An electric field $\vec{E}$ given by :\n$\vec{E} = 100\hat{i}\frac{\text{N}}{\text{C}} \quad \text{for } x > 0$\n$= -100\hat{i}\frac{\text{N}}{\text{C}} \quad \text{for } x < 0$\nexists in a region. A right circular cylinder of length $10\text{ cm}$ and radius $2\text{ cm}$, is placed in the region such that its axis coincides with x-axis and its two faces are at $x = -5\text{ cm}$ and $x = 5\text{ cm}$. Calculate:\n(a) the net outward flux through the cylinder, and\n(b) the net charge inside the cylinder.

Answer the following, giving reasons:\n(a) The maximum kinetic energy of the photoelectrons is independent of the intensity of incident radiation.\n(b) Photoelectric current increases with the increase in the intensity of the incident radiation.\n(c) The stopping potential $V_0$ varies linearly with the frequency $\nu$ of the incident radiation for a given photosensitive surface.

Name the electromagnetic radiations and write their frequency range:\n(a) Used to take the photograph of the bones\n(b) Produced by hot bodies\n(c) Used in television communication systems

(b) (i) Two coherent light waves, each of intensity $I_0$ superpose each other and produce interference pattern on a screen. Obtain the expression for the resultant intensity at a point where the phase difference between the waves is $\phi$. Write its maximum and minimum possible values.\n(ii) In a single slit diffraction experiment, the aperture of the slit is $3\text{ mm}$ and the separation between the slit and the screen is $1.5\text{ m}$. A monochromatic light of wavelength $600\text{ nm}$ is normally incident on the slit. Calculate the distance of (I) first order minimum, and (II) second order maximum, from the centre of the screen.

(b) (i) An electric dipole of dipole moment $p$ consists of point charges $q$ and $-q$, separated by $2a$. Derive an expression for electric potential in terms of its dipole moment at a point at a distance $x (x >> a)$ from its centre and lying (I) along its axis, and (II) along its bisector line.\n(ii) An electric dipole of dipole moment $\vec{p} = (0.8\hat{i} + 0.6\hat{j}) \times 10^{-29}\text{ C m}$ is placed in an electric field $\vec{E} = 1.0 \times 10^7 \hat{k}\ \text{V/m}$. Calculate the magnitude of the torque acting on it and the angle it makes with the x-axis, at this instant.

(b) (i) (I) Write Ampere's circuital law in mathematical form and explain the terms used.\n(II) As the current carrying solenoid is made longer, the magnetic field produced outside it approaches zero. Why?\n(III) A flexible loop of irregular shape carrying current when located in an external magnetic field, changes to a circular shape. Give reason.\n(ii) A galvanometer of resistance $G$ is converted into a voltmeter to measure up to $V$ volts, by connecting a resistance $R_1$ in series with the coil. If $R_1$ is replaced by $R_2$, then it can only measure up to $\frac{V}{2}$ volt. Find the value of the resistance $R_3$ (in terms of $R_1$ and $R_2$) needed to convert it into a voltmeter that can read up to $2V$.

Write the mathematical forms of three postulates of Bohr's theory of the hydrogen atom. Using them prove that, for an electron revolving in the $n^{\text{th}}$ orbit,\n(a) the radius of the orbit is proportional to $n^2$, and\n(b) the total energy of the atom is proportional to $\left(\frac{1}{n^2}\right)$.

Consider the contribution of the following two factors I and II in resistivity of a metal: I. Relaxation time of electrons II. Number of electrons per unit volume

The resistivity of a metal increases with increase in its temperature because:

A steady current flows in a copper wire of non-uniform cross-section. Consider the following three physical quantities: I. Electric field II. Current density III. Drift speed

At the different points along the wire:

The temperature coefficient of resistance of nichrome is $1.70 \times 10^{-4}\ ^\circ\text{C}^{-1}$. In order to increase resistance of a nichrome wire by 8.5%, the temperature of the wire should be increased by:

A wire of length $0.5\text{ m}$ and cross-sectional area $1.0 \times 10^{-7}\text{ m}^2$ is connected to a battery of $2\text{ V}$ that maintains a current of $1.5\text{ A}$ in it. The conductivity of the material of the wire (in $\Omega^{-1}\text{m}^{-1}$) is:

Consider two cylindrical conductors A and B, made of the same metal, connected in series to a battery. The length and the radius of B are twice that of A. If $\mu_A$ and $\mu_B$ are the mobility of electrons in A and B respectively, then the ratio $\frac{\mu_A}{\mu_B}$ is: