CBSE Class 12 2025 Physics 55-5-1 Question Paper Set-1: Download Solutions with Answer Key

A metal sheet is inserted between the plates of a parallel plate capacitor of capacitance C. If the sheet partly occupies the space between the plates, the capacitance:

• (A) remains C
• (B) becomes greater than C
• (C) becomes less than C
• (D) becomes zero

The electric field at a point in a region is given by \( \vec{E} = \alpha \frac{\hat{r}}{r^3} \), where \( \alpha \) is a constant and \( r \) is the distance of the point from the origin. The magnitude of potential of the point is:

• (A) \( \frac{\alpha}{r} \)
• (B) \( \frac{\alpha r^2}{2} \)
• (C) \( \frac{\alpha}{2r^2} \)
• (D) \( -\frac{\alpha}{r} \)

Four resistors, each of resistance R and a key K are connected as shown in the figure. The equivalent resistance between points A and B when key K is open will be:

• (A) \( 4R \)
• (B) \( \infty \)
• (C) \( \frac{R}{4} \)
• (D) \( \frac{3R}{2} \)

A charged particle gains a speed of \(10^6 \, ms^{-1}\) when accelerated from rest through a potential difference of 10 kV. It enters a region of magnetic field of 0.4 T such that \( \vec{v} \perp \vec{B} \). The radius of the circular path described by it is:

• (A) 2.5 cm
• (B) 5 cm
• (C) 8 cm
• (D) 10 cm

A current of \( \frac{10}{\pi} \) A is maintained in a circular loop of radius 14 cm. The value of dipole moment associated with the loop is:

• (A) 0.019 Am\(^2\)
• (B) 0.14 Am\(^2\)
• (C) 0.196 Am\(^2\)
• (D) 0.615 Am\(^2\)

The magnetic flux linked with a coil changes with time \( t \) as \( \phi = (8t^2 + 5t + 7) \), where \( t \) is in seconds and \( \phi \) is in Wb. The value of emf induced in the coil at \( t = 4 \) s is:

• (A) 32 V
• (B) 37 V
• (C) 64 V
• (D) 69 V

Which of the following rays coming from the Sun plays an important role in maintaining the Earth’s warmth?

• (A) Infrared rays
• (B) \( \gamma \) rays
• (C) UV rays
• (D) Visible light rays

The dimensions of \( (\mu \epsilon)^{-1} \), where \( \epsilon \) is permittivity and \( \mu \) is permeability of a medium, are:

• (A) \( [M^0 L^1 T^{-1}] \)
• (B) \( [M^0 L^2 T^{-2}] \)
• (C) \( [M^1 L^2 T^{-2}] \)
• (D) \( [M^1 L^{-1} T^{1}] \)

Which of the following electromagnetic waves has photons of largest momentum?

• (A) X-rays
• (B) AM radio waves
• (C) Microwaves
• (D) TV waves

A compound microscope has an objective and an eyepiece of focal lengths \( f_0 \) and \( f_e \), respectively. To obtain a large magnification of a small object, the microscope should have:

• (A) \( f_0 \) and \( f_e \) small, and \( f_e > f_0 \)
• (B) \( f_0 \) and \( f_e \) small, and \( f_0 > f_e \)
• (C) \( f_0 \) and \( f_e \) large, and \( f_e > f_0 \)
• (D) \( f_0 \) and \( f_e \) large, and \( f_0 > f_e \)

Two coherent light waves, each having amplitude ‘a’, superpose to produce an interference pattern on a screen. The intensity of light as seen on the screen varies between:

• (A) 0 and \( 2a^2 \)
• (B) 0 and \( 4a^2 \)
• (C) \( a^2 \) and \( 2a^2 \)
• (D) \( 2a^2 \) and \( 4a^2 \)

The kinetic energy of an alpha particle is four times the kinetic energy of a proton. The ratio \( \left( \frac{\lambda_\alpha}{\lambda_p} \right) \) of de Broglie wavelengths associated with them will be:

• (A) \( \frac{1}{16} \)
• (B) \( \frac{1}{8} \)
• (C) \( \frac{1}{4} \)
• (D) \( \frac{1}{2} \)

Two statements are given, one labelled Assertion (A) and the other labelled Reason (R). Select the correct answer from the codes (A), (B), (C), and (D) as given below.


Assertion (A): The impurities in p-type Si are not pentavalent atoms.

Reason (R): The hole density in the valence band in a p-type semiconductor is almost equal to the acceptor density.

• (A) Both Assertion (A) and Reason (R) are true, and Reason (R) is the correct explanation of Assertion (A).
• (B) Both Assertion (A) and Reason (R) are true, but Reason (R) is not the correct explanation of Assertion (A).
• (C) Assertion (A) is true, but Reason (R) is false.
• (D) Both Assertion (A) and Reason (R) are false.

Two statements are given, one labelled Assertion (A) and the other labelled Reason (R). Select the correct answer from the codes (A), (B), (C) and (D) as given below.


% Assertion
Assertion (A): During the formation of a nucleus, the mass defect produced is the source of the binding energy of the nucleus.

Reason (R): For all nuclei, the value of binding energy per nucleon increases with mass number.

• (A) Both Assertion (A) and Reason (R) are true, and Reason (R) is the correct explanation of Assertion (A).
• (B) Both Assertion (A) and Reason (R) are true, but Reason (R) is not the correct explanation of Assertion (A).
• (C) Assertion (A) is true, but Reason (R) is false.
• (D) Both Assertion (A) and Reason (R) are false.

Two statements are given, one labelled Assertion (A) and the other labelled Reason (R). Select the correct answer from the codes (A), (B), (C), and (D) as given below.

Two statements are given, one labelled Assertion (A) and the other labelled Reason (R). Select the correct answer from the codes (A), (B), (C) and (D) as given below.

Assertion (A): The Balmer series in the hydrogen atom spectrum is formed when the electron jumps from a higher energy state to the ground state.

Reason (R): In Bohr's model of the hydrogen atom, the electron can jump between successive orbits only.

• (A) Both Assertion (A) and Reason (R) are true, and Reason (R) is the correct explanation of Assertion (A).
• (B) Both Assertion (A) and Reason (R) are true, but Reason (R) is not the correct explanation of Assertion (A).
• (C) Assertion (A) is true, but Reason (R) is false.
• (D) Both Assertion (A) and Reason (R) are false.

Assertion (A): In Rutherford’s alpha particle scattering experiment, the presence of only few alpha particles at angle of scattering \( \pi \) led him to the discovery of the nucleus.

Reason (R): The size of the nucleus is approximately \( 10^{-5} \) times the size of an atom and therefore only few alpha particles are rebounded.

• (A) Both Assertion (A) and Reason (R) are true, and Reason (R) is the correct explanation of Assertion (A).
• (B) Both Assertion (A) and Reason (R) are true, but Reason (R) is not the correct explanation of Assertion (A).
• (C) Assertion (A) is true, but Reason (R) is false.
• (D) Both Assertion (A) and Reason (R) are false.

The threshold frequency for a given metal is \( 3.6 \times 10^{14} \) Hz. If monochromatic radiations of frequency \( 6.8 \times 10^{14} \) Hz are incident on this metal, find the cut-off potential for the photoelectrons.


% Given:
- Threshold frequency, \( \nu_0 = 3.6 \times 10^{14} \) Hz

- Frequency of incident radiation, \( \nu = 6.8 \times 10^{14} \) Hz

- Planck's constant, \( h = 6.63 \times 10^{-34} \, J \cdot s \)

- Charge of the electron, \( e = 1.6 \times 10^{-19} \, C \)

(a) A point object is placed in air at a distance \( \frac{R}{3} \) in front of a convex surface of radius of curvature \( R \), separating air from a medium of refractive index \( n \) (where \( n < 4 \)). Find the nature and position of the image formed.

A voltmeter of resistance 1000 \( \Omega \) can measure up to 25 V. How will you convert it so that it can read up to 250 V?

When a neutron collides with \( \,^{235}_{92}U \), the nucleus gives \( \,^{140}_{54}Xe \) and \( \,^{94}_{38}Sr \) as fission products, and two neutrons are ejected. Calculate the mass defect and the energy released (in MeV) in the process. Given: \[m(^{235}_{92}U) = 235.04393 \, u, \quad m(^{140}_{54}Xe) = 139.92164 \, u, \quad m(^{94}_{38}Sr) = 93.91536 \, u, \quad m(^{1}_0n) = 1.00866 \, u, \quad
1 \, u = 931 \, MeV/c^2\]

The resistance of a wire at 25°C is 10.0 \( \Omega \). When heated to 125°C, its resistance becomes 10.5 \( \Omega \). Find (i) the temperature coefficient of resistance of the wire, and (ii) the resistance of the wire at 425°C.

(a) Draw the energy-band diagram for conductors, semiconductors, and insulators at T = 0 K. How is an electron-hole pair formed in a semiconductor at room temperature?

A parallel plate capacitor has plate area \( A \) and plate separation \( d \). Half of the space between the plates is filled with a material of dielectric constant \( K \) in two ways as shown in the figure. Find the values of the capacitance of the capacitors in the two cases.

In Young's double slit experiment, the separation between the two slits is 1.0 mm and the screen is 1.0 m away from the slits. A beam of light consisting of two wavelengths, 500 nm and 600 nm, is used to obtain interference fringes. Calculate:



(a) The distance between the first maxima for the two wavelengths.

Differentiate between half-wave and full-wave rectification. With the help of a circuit diagram, explain the working of a full-wave rectifier.

An electron of mass \(m\) and charge \(-e\) is revolving anticlockwise around the nucleus of an atom.



(a) Obtain the expression for the magnetic dipole moment \(\mu\) of the atom.

A rectangular glass slab ABCD (refractive index 1.5) is surrounded by a transparent liquid (refractive index 1.25) as shown in the figure. A ray of light is incident on face AB at an angle \(i\) such that it is refracted out grazing the face AD. Find the value of angle \(i\).

Two small solid metal balls A and B of radii \(R\) and \(2R\) having charge densities 2 and 3 respectively are kept far apart. Find the charge densities on A and B after they are connected by a conducting wire.

Two infinitely long straight wires ‘1’ and ‘2’ are placed \(d\) distance apart, parallel to each other, as shown in the figure. They are uniformly charged having charge densities \(\lambda\) and \(-\frac{\lambda}{2}\) respectively. Locate the position of the point from wire ‘1’ at which the net electric field is zero and identify the region in which it lies.

The value of the current sensitivity of a galvanometer is given by:

• (A) \(\frac{k}{NBA}\)
• (B) \(\frac{NBA}{k}\)
• (C) \(\frac{kBA}{N}\)
• (D) \(\frac{kNB}{A}\)

A galvanometer of resistance 6 \(\Omega\) shows full scale deflection for a current of 0.2 A. The value of shunt to be used with this galvanometer to convert it into an ammeter of range (0 – 5 A) is:

• (A) 0.25 \(\Omega\)
• (B) 0.30 \(\Omega\)
• (C) 0.50 \(\Omega\)
• (D) 6.0 \(\Omega\)

The value of resistance of the ammeter in case (ii) will be:

• (A) 0.20 \(\Omega\)
• (B) 0.24 \(\Omega\)
• (C) 6.0 \(\Omega\)
• (D) 6.25 \(\Omega\)

A galvanometer is converted into a voltmeter of range (0 – V) by connecting with it, a resistance \(R_1\). If \(R_1\) is replaced by \(R_2\), the range becomes (0 – 2 V). The resistance of the galvanometer is:

• (A) \(R_2 - 2R_1\)
• (B) \(R_2 - R_1\)
• (C) \(R_1 + R_2\)
• (D) \(R_1 - 2R_2\)

A current of 5 mA flows through a galvanometer. Its coil has 100 turns, each of area of cross-section 18 cm\(^2\) and is suspended in a magnetic field of 0.20 T. The deflecting torque acting on the coil will be:

• (A) \(3.6 \times 10^{-3}\) Nm
• (B) \(1.8 \times 10^{-4}\) Nm
• (C) \(2.4 \times 10^{-3}\) Nm
• (D) \(1.2 \times 10^{-4}\) Nm

Which of the following graphs shows the variation of photoelectric current \(I\) with the intensity of light?

When the frequency of the incident light is increased without changing its intensity, the saturation current:

• (A) increases linearly
• (B) decreases
• (C) increases non-linearly
• (D) remains the same

Which of the following graphs can be used to obtain the value of Planck’s constant?

• (A) \textbf{Photocurrent versus Intensity of incident light}
• (B) \textbf{Photocurrent versus Frequency of incident light}
• (C) \textbf{Cut-off potential versus Frequency of incident light}
• (D) \textbf{Cut-off potential versus Intensity of incident light}

Red light, yellow light, and blue light of the same intensity are incident on a metal surface successively. \(K_R\), \(K_Y\), and \(K_B\) represent the maximum kinetic energy of photoelectrons respectively, then:

• (A) \(K_R > K_Y > K_B\)
• (B) \(K_Y > K_B > K_R\)
• (C) \(K_B > K_Y > K_R\)
• (D) \(K_R > K_B > K_Y\)

Which of the following metals exhibits photoelectric effect with visible light?

• (A) \textbf{Caesium}
• (B) \textbf{Zinc}
• (C) \textbf{Cadmium}
• (D) \textbf{Magnesium}

Three batteries E1, E2, and E3 of emfs and internal resistances (4 V, 2 \(\Omega\)), (2 V, 4 \(\Omega\)) and (6 V, 2 \(\Omega\)) respectively are connected as shown in the figure. Find the values of the currents passing through batteries E1, E2, and E3.

The ends of six wires, each of resistance R (= 10 \(\Omega\)) are joined as shown in the figure. The points A and B of the arrangement are connected in a circuit. Find the value of the effective resistance offered by it to the circuit.

Current I (= 1 A) is passing through a copper rod (n = \(8.5 \times 10^{28} \, m^{-3}\)) of varying cross-sections as shown in the figure. The areas of cross-section at points A and B along its length are \(1.0 \times 10^{-7} \, m^2\) and \(2.0 \times 10^{-7} \, m^2\) respectively. Calculate:




(I) the ratio of electric fields at points A and B.

(II) the drift velocity of free electrons at point B.

Two point charges \( q_1 = 16 \, \mu C \) and \( q_2 = 1 \, \mu C \) are placed at points \( \vec{r}_1 = (3 \, m) \hat{i} \) and \( \vec{r}_2 = (4 \, m) \hat{j} \). Find the net electric field \( \vec{E} \) at point \( \vec{r} = (3 \, m) \hat{i} + (4 \, m) \hat{j} \).

Define self-inductance of a coil. Derive the expression for the energy required to build up a current \(I\) in a coil of self-inductance \(L\).

Define the term mutual inductance. Deduce the expression for the mutual inductance of two long coaxial solenoids of the same length having different radii and different number of turns.

The current through an inductor is uniformly increased from zero to 2 A in 40 s. An emf of 5 mV is induced during this period. Find the flux linked with the inductor at t = 10 s.

Draw a ray diagram of a reflecting telescope (Cassegrain) and explain the formation of the image. State two important advantages that a reflecting telescope has over a refracting telescope.

In a refracting telescope, the focal length of the objective is 50 times the focal length of the eyepiece. When the final image is formed at infinity, the length of the tube is 102 cm. Find the focal lengths of the two lenses.

Write any two advantages of a compound microscope over a simple microscope. Draw a ray diagram for the image formation at the near point by a compound microscope and explain it.

A thin plano-concave lens with its curved face of radius of curvature R is made of glass of refractive index \( n_1 \). It is placed coaxially in contact with a thin equiconvex lens of same radius of curvature of refractive index \( n_2 \). Obtain the power of the combination lens.