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99 values
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1
1
standard
A thin plastic rod is bent into a circular ring of radius R. It is uniformly charged with charge density $\lambda$. The magnitude of the electric field at its centre is :
1
[ "Electric Charges", "Electric Field", "Electric Field due to continuous charge distribution" ]
Electric Charges and Fields
null
null
{ "A": "$\\frac{\\lambda}{2\\varepsilon_0R}$", "B": "Zero", "C": "$\\frac{\\lambda}{4\\pi\\varepsilon_0R}$", "D": "$\\frac{\\lambda}{4\\varepsilon_0R}$" }
null
false
null
null
null
null
2
2
standard
Ten capacitors, each of capacitance 1 $\mu$F, are connected in parallel to a source of 100 V. The total energy stored in the system is equal to :
1
[ "Capacitors", "Combination of capacitors", "Energy stored in a capacitor" ]
Electrostatic Potential and Capacitance
null
null
{ "A": "$10^{-2}$ J", "B": "$10^{-3}$ J", "C": "$0.5 \\times 10^{-3}$ J", "D": "$5.0 \\times 10^{-2}$ J" }
null
false
null
null
null
null
3
3
standard
Consider the circuit shown in the figure. The potential difference between points A and B is :
1
[ "Electric current", "Ohm's law", "Kirchhoff's rules" ]
Current Electricity
[ "img\\img_1.jpeg" ]
null
{ "A": "6 V", "B": "8 V", "C": "9 V", "D": "12 V" }
null
false
null
null
null
null
4
4
standard
A loop carrying a current I clockwise is placed in x – y plane, in a uniform magnetic field directed along z-axis. The tendency of the loop will be to :
1
[ "Magnetic field", "Force on a current-carrying conductor in a uniform magnetic field", "Torque on a current loop" ]
Moving Charges and Magnetism
null
null
{ "A": "move along x-axis", "B": "move along y-axis", "C": "shrink", "D": "expand" }
null
false
null
null
null
null
5
5
standard
A 10 cm long wire lies along y-axis. It carries a current of 1.0 A in positive y-direction. A magnetic field $\vec{B} = (5 \text{ mT}) \hat{j} - (8 \text{ mT})\hat{k}$ exists in the region. The force on the wire is :
1
[ "Magnetic field", "Force on a current-carrying conductor in a uniform magnetic field" ]
Moving Charges and Magnetism
null
null
{ "A": "$(0.8 \\text{ mN}) \\hat{i}$", "B": "$-(0.8 \\text{ mN}) \\hat{i}$", "C": "$(80 \\text{ mN}) \\hat{i}$", "D": "$-(80 \\text{ mN}) \\hat{i}$" }
null
false
null
null
null
null
6
6
standard
A galvanometer of resistance GΞ© is converted into an ammeter of range O to I A. If the current through the galvanometer is 0.1% of I A, the resistance of the ammeter is :
1
[ "Moving Coil Galvanometer", "Ammeter Conversion", "Shunt Resistance" ]
Moving Charges and Magnetism
null
null
{ "A": "$\\frac{G}{999} \\Omega$", "B": "$\\frac{G}{1000} \\Omega$", "C": "$\\frac{G}{1001} \\Omega$", "D": "$\\frac{G}{100-1} \\Omega$" }
null
false
null
null
null
null
7
7
standard
The reactance of a capacitor of capacitance C connected to an ac source of frequency Ο‰ is β€˜X'. If the capacitance of the capacitor is doubled and the frequency of the source is tripled, the reactance will become :
1
[ "Capacitive Reactance", "Alternating Current Circuits" ]
Alternating Current
null
null
{ "A": "$\\frac{X}{6}$", "B": "$6X$", "C": "$\\frac{2}{3}X$", "D": "$\\frac{3}{2}X$" }
null
false
null
null
null
null
8
8
standard
In the four regions, I, II, III and IV, the electric fields are described as : Region I : Eβ‚“ = Eβ‚€ sin (kz – Ο‰t) Region II : Eβ‚“ = Eβ‚€ Region III: Eβ‚“ = Eβ‚€ sin kz Region IV: Eβ‚“ = Eβ‚€ cos kz The displacement current will exist in the region :
1
[ "Displacement Current", "Electromagnetic Waves" ]
Electromagnetic Waves
null
null
{ "A": "I", "B": "IV", "C": "II", "D": "III" }
null
false
null
null
null
null
9
9
standard
The transition of electron that gives rise to the formation of the second spectral line of the Balmer series in the spectrum of hydrogen atom corresponds to :
1
[ "Hydrogen Spectrum", "Balmer Series", "Atomic Transitions" ]
Atoms
null
null
{ "A": "n<0xE1><0xB5> = 2 and n<0xE2><0x82><0x81> = 3", "B": "n<0xE1><0xB5> = 3 and n<0xE2><0x82><0x81> = 4", "C": "n<0xE1><0xB5> = 2 and n<0xE2><0x82><0x81> = 4", "D": "n<0xE1><0xB5> = 2 and n<0xE2><0x82><0x81> = ∞" }
null
false
null
null
null
null
10
10
standard
Ge is doped with As. Due to doping,
1
[ "Semiconductors", "Doping", "Extrinsic Semiconductors", "n-type Semiconductor" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "the structure of Ge lattice is distorted.", "B": "the number of conduction electrons increases.", "C": "the number of holes increases.", "D": "the number of conduction electrons decreases." }
null
false
null
null
null
null
11
11
standard
Two beams, A and B whose photon energies are 3.3 eV and 11.3 eV respectively, illuminate a metallic surface (work function 2.3 eV) successively. The ratio of maximum speed of electrons emitted due to beam A to that due to beam B is :
1
[ "Photoelectric Effect", "Einstein's Photoelectric Equation", "Kinetic Energy of Photoelectrons" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "3", "B": "9", "C": "$\\frac{1}{3}$", "D": "$\\frac{1}{9}$" }
null
false
null
null
null
null
12
12.
standard
The waves associated with a moving electron and a moving proton have the same wavelength \(\lambda\). It implies that they have the same :
1
[ "de-Broglie relation", "momentum" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "momentum", "B": "angular momentum", "C": "speed", "D": "energy" }
null
false
null
null
null
null
13
13.
assertion_reason
null
1
[ "Photoelectric effect", "Einstein's photoelectric equation" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "Both Assertion and Reason are true and Reason is the correct explanation of Assertion", "B": "Both Assertion and Reason are true but Reason is not the correct explanation of Assertion", "C": "Assertion is true but Reason is false", "D": "Both Assertion and Reason are false" }
null
null
null
null
null
null
14
14.
assertion_reason
null
1
[ "Mutual induction", "Magnetic flux" ]
Electromagnetic Induction
null
null
{ "A": "Both Assertion and Reason are true and Reason is the correct explanation of Assertion", "B": "Both Assertion and Reason are true but Reason is not the correct explanation of Assertion", "C": "Assertion is true but Reason is false", "D": "Both Assertion and Reason are false" }
null
null
null
null
null
null
15
15.
assertion_reason
null
1
[ "Force between two parallel current-carrying conductors", "Ampere's law" ]
Moving Charges and Magnetism
null
null
{ "A": "Both Assertion and Reason are true and Reason is the correct explanation of Assertion", "B": "Both Assertion and Reason are true but Reason is not the correct explanation of Assertion", "C": "Assertion is true but Reason is false", "D": "Both Assertion and Reason are false" }
null
null
null
null
null
null
16
16.
assertion_reason
null
1
[ "Reflection of light", "Spherical mirrors", "Image formation" ]
Ray Optics and Optical Instruments
null
null
{ "A": "Both Assertion and Reason are true and Reason is the correct explanation of Assertion", "B": "Both Assertion and Reason are true but Reason is not the correct explanation of Assertion", "C": "Assertion is true but Reason is false", "D": "Both Assertion and Reason are false" }
null
null
null
null
null
null
17
17
standard
Find the temperature at which the resistance of a wire made of silver will be twice its resistance at 20Β°C. Take 20Β°C as the reference temperature and temperature coefficient of resistance of silver at 20Β°C = 4.0 Γ— 10⁻³ K⁻¹.
2
[ "Temperature dependence of resistance", "Electrical resistivity and conductivity" ]
Current Electricity
null
null
null
null
false
null
null
null
null
18
18
standard
Monochromatic light of frequency 5.0 Γ— 10¹⁴ Hz passes from air into a medium of refractive index 1.5. Find the wavelength of the light (i) reflected, and (ii) refracted at the interface of the two media.
2
[ "Refraction of light", "Reflection of light", "Wave optics" ]
Ray Optics and Optical Instruments
null
null
null
null
false
null
null
null
null
19
19
standard
An object is placed 30 cm in front of a concave mirror of radius of curvature 40 cm. Find the (i) position of the image formed and (ii) magnification of the image.
2
[ "Reflection of light", "Spherical mirrors", "Mirror formula", "Magnification" ]
Ray Optics and Optical Instruments
null
null
null
null
false
null
null
null
null
20
20
standard
Consider a neutron (mass m) of kinetic energy E and a photon of the same energy. Let Ξ»β‚™ and Ξ»β‚š be the de Broglie wavelength of neutron and the wavelength of photon respectively. Obtain an expression for Ξ»β‚™ / Ξ»β‚š.
2
[ "Dual nature of radiation", "Matter waves", "de-Broglie relation", "Photoelectric effect" ]
Dual Nature of Radiation and Matter
null
null
null
null
false
null
null
null
null
21
21
standard
Plot a graph showing the variation of current with voltage for the material GaAs. On the graph, mark the region where : (a) resistance is negative, and (b) Ohm's law is obeyed.
2
[ "Electric current", "Ohm's law", "V-I characteristics", "Semiconductors" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
null
null
false
null
null
null
null
22
22.
standard
A cube of side 0.1 m is placed, as shown in the figure, in a region where electric field $\vec{E} = 500 x \hat{i}$ exists. Here x is in meters and E in NC$^{-1}$. Calculate :
3
[ "Electric flux", "Gauss's theorem" ]
Electric Charges and Fields
[ "img\\img_2.jpeg" ]
null
null
null
false
null
null
null
null
23
23.
standard
Define 'current density'. Is it a scalar or a vector ? An electric field $\vec{E}$ is maintained in a metallic conductor. If n be the number of electrons (mass m, charge – e) per unit volume in the conductor and $\tau$ its relaxation time, show that the current density $\vec{j} = \alpha \vec{E}$, where $\alpha = \left( \frac{ne^2}{m} \right) \tau$.
3
[ "Current density", "Drift velocity", "Ohm's law" ]
Current Electricity
null
null
null
null
false
null
null
null
null
24
24.
standard
A proton with kinetic energy $1.3384 \times 10^{-14}$ J moving horizontally from north to south, enters a uniform magnetic field B of 2.0 mT directed eastward. Calculate :
3
[ "Force on a moving charge in magnetic field", "Motion in a magnetic field" ]
Moving Charges and Magnetism
null
null
null
null
false
null
null
null
null
25
25.
standard
An inductor, a capacitor and a resistor are connected in series with an ac source v = $v_m$ sin $\omega$t. Derive an expression for the average power dissipated in the circuit. Also obtain the expression for the resonant frequency of the circuit.
3
[ "AC Circuits", "Average Power", "Resonance" ]
Alternating Current
null
null
null
null
false
null
null
null
null
26
26.
standard
(a) β€œThe wavelength of the electromagnetic wave is often correlated with the characteristic size of the system that radiates.” Give two examples to justify this statement.
3
[ "Electromagnetic Waves", "Radiation" ]
Electromagnetic Waves
null
null
null
null
false
null
null
null
null
27
27.
standard
Write the drawbacks of Rutherford's atomic model. How did Bohr remove them ? Show that different orbits in Bohr's atom are not equally spaced.
3
[ "Rutherford's Atomic Model", "Bohr's Model", "Atomic Spectra" ]
Atoms
null
null
null
null
false
null
null
null
null
28
28.
standard
(a) State any two properties of a nucleus. (b) Why is the density of a nucleus much more than that of an atom ? (c) Show that the density of the nuclear matter is the same for all nuclei.
3
[ "Nucleus", "Nuclear Density" ]
Nuclei
null
null
null
null
false
null
null
null
null
29
29
case_study
null
15
[ "Lenses", "Focal Length", "Refractive Index", "Power of a Lens", "Combination of Lenses" ]
Ray Optics and Optical Instruments
null
null
null
null
null
null
null
null
null
30
(i)
standard
A double-convex lens, with each face having same radius of curvature R, is made of glass of refractive index n. Its power is :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Lens maker’s formula" ]
Ray Optics and Optical Instruments
null
null
{ "A": "$\\frac{2 (n - 1)}{R}$", "B": "$\\frac{(2n - 1)}{R}$", "C": "$\\frac{(n - 1)}{2R}$", "D": "$\\frac{(2n – 1)}{2R}$" }
null
false
null
null
null
null
31
(ii)
standard
A double-convex lens of power P, with each face having same radius of curvature, is cut into two equal parts perpendicular to its principal axis. The power of one part of the lens will be :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Combination of thin lenses in contact" ]
Ray Optics and Optical Instruments
null
null
{ "A": "2P", "B": "P", "C": "4P", "D": "$\\frac{P}{2}$" }
null
false
null
null
null
null
32
(iii)
standard
The above two parts are kept in contact with each other as shown in the figure. The power of the combination will be :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Combination of thin lenses in contact" ]
Ray Optics and Optical Instruments
[ "img\\img_3.jpeg" ]
null
{ "A": "$\\frac{P}{2}$", "B": "P", "C": "2P", "D": "$\\frac{P}{4}$" }
null
false
null
null
null
null
33
(iv)
standard
A double-convex lens of power P, with each face having same radius of curvature, is cut along its principal axis. The two parts are arranged as shown in the figure. The power of the combination will be :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Combination of thin lenses in contact" ]
Ray Optics and Optical Instruments
[ "img\\img_4.jpeg" ]
null
{ "A": "Zero", "B": "P", "C": "2P", "D": "$\\frac{P}{2}$" }
null
false
null
null
null
null
34
30
case_study
null
3
[ "Semiconductor diode", "Rectifier", "Forward bias", "Reverse bias", "Half-wave rectifier", "Full-wave rectifier" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
null
null
null
null
null
null
null
35
(iv)(a)
standard
An alternating voltage of frequency of 50 Hz is applied to a half-wave rectifier. Then the ripple frequency of the output will be :
1
[ "Rectifiers", "Ripple frequency" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "100 Hz", "B": "50 Hz", "C": "25 Hz", "D": "150 Hz" }
null
false
null
null
null
null
36
31.
standard
(a) (i) Derive an expression for potential energy of an electric dipole $\vec{p}$ in an external uniform electric field $\vec{E}$. When is the potential energy of the dipole (1) maximum, and (2) minimum ? (ii) An electric dipole consists of point charges – 1.0 pC and + 1.0 pC located at (0, 0) and (3 mm, 4 mm) respectively in x – y plane. An electric field $\vec{E} = \left(\frac{1000 \text{ V}}{\text{m}}\right) \hat{i}$ is switched on in the region. Find the torque $\vec{\tau}$ acting on the dipole.
5
[ "Electric Dipole", "Potential Energy", "Torque" ]
Electrostatic Potential and Capacitance
null
null
null
null
false
null
null
null
null
37
32.
standard
(a) (i) A resistor and a capacitor are connected in series to an ac source $v = v_m \sin \omega t$. Derive an expression for the impedance of the circuit. (ii) When does an inductor act as a conductor in a circuit ? Give reason for it.
5
[ "AC Circuits", "Impedance", "Inductors" ]
Alternating Current
null
null
null
null
false
null
null
null
null
38
33. (a)
standard
null
5
[ "Refraction of light through a prism", "Angle of deviation", "Angle of minimum deviation", "Refractive index" ]
Ray Optics and Optical Instruments
[]
null
null
null
false
null
null
null
null
39
33. (b)
standard
null
5
[ "AC Circuits", "Inductance", "Impedance" ]
Alternating Current
[]
null
null
null
false
null
null
null
null
40
(iii)
standard
The refractive index of the material of a prism is $\sqrt{2}$. If the refracting angle of the prism is $60^\circ$, find the
5
[ "Refraction of light through a prism", "Angle of minimum deviation" ]
Ray Optics and Optical Instruments
null
null
null
null
false
null
null
null
null
41
1
standard
A thin plastic rod is bent into a circular ring of radius R. It is uniformly charged with charge density \(\lambda\). The magnitude of the electric field at its centre is :
1
[ "Electric Charges", "Electric Fields", "Electric field due to continuous charge distribution" ]
Chapter–1
null
null
{ "A": "\\(\\frac{\\lambda}{2\\varepsilon_0 R}\\)", "B": "Zero", "C": "\\(\\frac{\\lambda}{4\\pi\\varepsilon_0 R}\\)", "D": "\\(\\frac{\\lambda}{4\\varepsilon_0 R}\\)" }
null
null
null
null
null
null
42
2
standard
A charged sphere of radius r has surface charge density \(\sigma\). The electric field on its surface is E. If the radius of the sphere is doubled, keeping charge density the same, the ratio of the electric field on the old sphere to that on the new sphere will be :
1
[ "Electric Charges", "Electric Fields", "Electric field due to a charged sphere" ]
Chapter–1
null
null
{ "A": "1", "B": "\\(\\frac{1}{2}\\)", "C": "\\(\\frac{1}{4}\\)", "D": "4" }
null
null
null
null
null
null
43
3
standard
A student is asked to connect four cells, each of emf E and internal resistance r, in series. But she/he connects one cell wrongly in series with the other cells. The equivalent emf and the equivalent internal resistance of the combination will be :
1
[ "Current Electricity", "Cells in series" ]
Chapter–3
null
null
{ "A": "4E and 2r", "B": "4E and 3r", "C": "3E and 4r", "D": "2E and 4r" }
null
null
null
null
null
null
44
4
standard
A piece of wire bent in the form of a circular loop A carries a current I. The wire is then bent into a circular loop B of two turns and carries the same current. The ratio of magnetic fields at the centre of loop A to that of loop B will be :
1
[ "Moving Charges and Magnetism", "Magnetic field due to a current carrying loop" ]
Chapter–4
null
null
{ "A": "\\(\\frac{1}{16}\\)", "B": "16", "C": "4", "D": "\\(\\frac{1}{4}\\)" }
null
null
null
null
null
null
45
5
standard
A 10 cm long wire lies along y-axis. It carries a current of 1.0 A in positive y-direction. A magnetic field \(\vec{B} = (5 \text{mT}) \hat{j} - (8 \text{mT})\hat{k}\) exists in the region. The force on the wire is :
1
[ "Moving Charges and Magnetism", "Force on a current-carrying conductor in a uniform magnetic field" ]
Chapter–4
null
null
{ "A": "\\((0.8 \\text{mN}) \\hat{i}\\)", "B": "\\((-0.8 \\text{mN}) \\hat{i}\\)", "C": "\\((80 \\text{mN}) \\hat{i}\\)", "D": "\\((-80 \\text{mN}) \\hat{i}\\)" }
null
null
null
null
null
null
46
6.
standard
A galvanometer of resistance G Ξ© is converted into an ammeter of range 0 to I A. If the current through the galvanometer is 0.1% of I A, the resistance of the ammeter is :
1
[ "Moving Coil Galvanometer", "Ammeter Conversion", "Shunt Resistance" ]
Moving Charges and Magnetism
null
null
{ "A": "$\\frac{G}{999} \\Omega$", "B": "$\\frac{G}{1000} \\Omega$", "C": "$\\frac{G}{1001} \\Omega$", "D": "$\\frac{G}{100-1} \\Omega$" }
null
false
null
null
null
null
47
7.
standard
A conducting circular loop is placed in a uniform magnetic field B = 50 mT with its plane perpendicular to the magnetic field. The radius of the loop is made to shrink at a constant rate of 1 mm s⁻¹. At the instant the radius of the loop is 4 cm, the induced emf in the loop is :
1
[ "Electromagnetic Induction", "Faraday's Law", "Induced EMF" ]
Electromagnetic Induction
null
null
{ "A": "$\\pi \\mu V$", "B": "$2\\pi \\mu V$", "C": "$4\\pi \\mu V$", "D": "$8\\pi \\mu V$" }
null
false
null
null
null
null
48
8.
standard
The electric and magnetic fields of electromagnetic waves are :
1
[ "Electromagnetic Waves", "Properties of EM Waves" ]
Electromagnetic Waves
null
null
{ "A": "In the same phase and perpendicular to each other.", "B": "In the same phase and not perpendicular to each other.", "C": "Not in the same phase but are perpendicular to each other.", "D": "Neither in the same phase nor perpendicular to each other." }
null
false
null
null
null
null
49
9.
standard
Two beams, A and B whose photon energies are 3.3 eV and 11.3 eV respectively, illuminate a metallic surface (work function 2.3 eV) successively. The ratio of maximum speed of electrons emitted due to beam A to that due to beam B is :
1
[ "Dual Nature of Radiation and Matter", "Photoelectric Effect", "Einstein's Photoelectric Equation" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "3", "B": "9", "C": "$\\frac{1}{3}$", "D": "$\\frac{1}{9}$" }
null
false
null
null
null
null
50
10.
standard
The waves associated with a moving electron and a moving proton have the same wavelength $\lambda$. It implies that they have the same :
1
[ "Dual Nature of Radiation and Matter", "Matter Waves", "de-Broglie relation" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "momentum", "B": "angular momentum", "C": "speed", "D": "energy" }
null
false
null
null
null
null
51
11.
standard
Ge is doped with As. Due to doping,
1
[ "Semiconductor Electronics", "Doping", "Extrinsic Semiconductors" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "the structure of Ge lattice is distorted.", "B": "the number of conduction electrons increases.", "C": "the number of holes increases.", "D": "the number of conduction electrons decreases." }
null
false
null
null
null
null
52
12
standard
The transition of electron that gives rise to the formation of the second spectral line of the Balmer series in the spectrum of hydrogen atom corresponds to :
1
[ "Balmer series", "Hydrogen spectrum", "Atomic spectra" ]
Atoms
null
null
{ "A": "nf = 2 and n₁ = 3", "B": "nf = 3 and n₁ = 4", "C": "nf = 2 and n₁ = 4", "D": "nf = 2 and n₁ = ∞" }
null
false
null
null
null
null
53
13
assertion_reason
null
1
[ "Reflection of light", "Mirrors", "Real and virtual images" ]
Ray Optics and Optical Instruments
null
null
{ "A": "Both Assertion (A) and Reason (R) are true and Reason (R) is the correct explanation of the Assertion (A).", "B": "Both Assertion (A) and Reason (R) are true but Reason (R) is not the correct explanation of the Assertion (A).", "C": "Assertion (A) is true, but Reason (R) is false.", "D": "Assertion (A) is false and Reason (R) is also false." }
null
null
null
null
null
null
54
14
assertion_reason
null
1
[ "Force between parallel currents", "Magnetic force on a current-carrying conductor" ]
Moving Charges and Magnetism
null
null
{ "A": "Both Assertion (A) and Reason (R) are true and Reason (R) is the correct explanation of the Assertion (A).", "B": "Both Assertion (A) and Reason (R) are true but Reason (R) is not the correct explanation of the Assertion (A).", "C": "Assertion (A) is true, but Reason (R) is false.", "D": "Assertion (A) is false and Reason (R) is also false." }
null
null
null
null
null
null
55
15
assertion_reason
null
1
[ "Photoelectric effect", "Kinetic energy of photoelectrons", "Intensity of light", "Wavelength of light" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "Both Assertion (A) and Reason (R) are true and Reason (R) is the correct explanation of the Assertion (A).", "B": "Both Assertion (A) and Reason (R) are true but Reason (R) is not the correct explanation of the Assertion (A).", "C": "Assertion (A) is true, but Reason (R) is false.", "D": "Assertion (A) is false and Reason (R) is also false." }
null
null
null
null
null
null
56
16
assertion_reason
null
1
[ "Mutual inductance", "Magnetic flux linkage" ]
Electromagnetic Induction
null
null
{ "A": "Both Assertion (A) and Reason (R) are true and Reason (R) is the correct explanation of the Assertion (A).", "B": "Both Assertion (A) and Reason (R) are true but Reason (R) is not the correct explanation of the Assertion (A).", "C": "Assertion (A) is true, but Reason (R) is false.", "D": "Assertion (A) is false and Reason (R) is also false." }
null
null
null
null
null
null
57
17
standard
Two batteries of emfs 6 V and 3 V and internal resistances 0.8 Ξ© and 0.2 Ξ© respectively are connected in series to an external resistance R, as shown in figure. Find the value of R so that the potential difference across the 6 V battery be zero.
2
[ "Internal resistance", "Series combination of cells", "Ohm's law" ]
Current Electricity
[ "img\\img_10.jpeg" ]
null
null
null
false
null
null
null
null
58
18
standard
Consider a neutron (mass m) of kinetic energy E and a photon of the same energy. Let $\lambda_n$ and $\lambda_p$ be the de Broglie wavelength of neutron and the wavelength of photon respectively. Obtain an expression for $\frac{\lambda_n}{\lambda_p}$.
2
[ "de Broglie wavelength", "Wave nature of particles", "Energy of a photon" ]
Dual Nature of Radiation and Matter
null
null
null
null
false
null
null
null
null
59
19
standard
Monochromatic light of frequency $5.0 \times 10^{14}$ Hz passes from air into a medium of refractive index 1.5. Find the wavelength of the light (i) reflected, and (ii) refracted at the interface of the two media.
2
[ "Reflection of light", "Refraction of light", "Wavelength and refractive index" ]
Ray Optics and Optical Instruments
null
null
null
null
false
null
null
null
null
60
20
standard
An object is placed 30 cm in front of a concave mirror of radius of curvature 40 cm. Find the (i) position of the image formed and (ii) magnification of the image.
2
[ "Mirror formula", "Magnification" ]
Ray Optics and Optical Instruments
null
null
null
null
false
null
null
null
null
61
21
standard
How does the conductivity of an intrinsic semiconductor vary with temperature ? Explain. Show the variation in a plot.
2
[ "Conductivity of semiconductors", "Temperature dependence of conductivity", "Intrinsic semiconductors" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
null
null
false
null
null
null
null
62
22.
standard
Three point charges Q₁, Qβ‚‚ and Q₃ are located in x – y plane at points (βˆ’ d, 0), (0, 0) and (d, 0) respectively. Q₁ and Q₃ are identical and Qβ‚‚ is positive. What will be the nature and value of Q₁ so that the potential energy of the system is zero ?
3
[ "Electric Charges", "Potential Energy of a System of Charges" ]
Electric Charges and Fields
null
null
null
null
false
null
null
null
null
63
23.
standard
Define 'current density'. Is it a scalar or a vector ? An electric field β†’ E is maintained in a metallic conductor. If n be the number of electrons (mass m, charge – e) per unit volume in the conductor and Ο„ its relaxation time, show that the current density β†’ j = Ξ± β†’ E, where Ξ± = ( neΒ²/m ) Ο„.
3
[ "Current Density", "Drift Velocity", "Ohm's Law" ]
Current Electricity
null
null
null
null
false
null
null
null
null
64
24.
standard
A bar magnet of magnetic moment 2.5 JT⁻¹ lies aligned with the direction of a uniform magnetic field of 0.32 T.
3
[ "Torque on a Magnetic Dipole", "Work Done on a Magnetic Dipole" ]
Magnetism and Matter
null
null
null
null
false
null
null
null
null
65
25.
standard
Consider the arrangement of two coils P and Q shown in the figure. When current in coil P is switched on or switched off, a current flows in coil Q.
3
[ "Electromagnetic Induction", "Faraday's Laws", "Lenz's Law" ]
Electromagnetic Induction
[ "img\\img_11.jpeg" ]
null
null
null
false
null
null
null
null
66
26
standard
Write the drawbacks of Rutherford's atomic model. How did Bohr remove them? Show that different orbits in Bohr's atom are not equally spaced.
3
[ "Rutherford's model of atom", "Bohr model of hydrogen atom", "Atomic spectra" ]
Atoms
null
null
null
null
false
null
null
null
null
67
27
standard
"The wavelength of the electromagnetic wave is often correlated with the characteristic size of the system that radiates." Give two examples to justify this statement.
3
[ "Electromagnetic waves", "Electromagnetic spectrum" ]
Electromagnetic Waves
null
null
null
null
false
null
null
null
null
68
27
standard
Long distance radio broadcasts use short-wave bands. Why?
null
[ "Electromagnetic waves", "Radio waves" ]
Electromagnetic Waves
null
null
null
null
false
null
null
null
null
69
27
standard
Optical and radio telescopes are built on the ground, but X-ray astronomy is possible only from satellites orbiting the Earth. Why?
null
[ "Electromagnetic waves", "Optical instruments", "Radio waves", "X-rays" ]
Electromagnetic Waves
null
null
null
null
false
null
null
null
null
70
28
standard
Write two characteristic properties of nuclear force.
null
[ "Nuclear force" ]
Nuclei
null
null
null
null
false
null
null
null
null
71
28
standard
Draw a plot of potential energy of a pair of nucleons as a function of their separation. Write two important conclusions that can be drawn from the plot.
3
[ "Nuclear force", "Potential energy" ]
Nuclei
null
null
null
null
false
null
null
null
null
72
29
case_study
null
15
[ "p-n junction", "Semiconductor diode", "Rectifier", "Forward bias", "Reverse bias", "Half-wave rectifier", "Full-wave rectifier" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
null
null
null
null
null
null
null
73
(i)
standard
The root mean square value of an alternating voltage applied to a full-wave rectifier is $\frac{V_0}{\sqrt{2}}$. Then the root mean square value of the rectified output voltage is :
1
[ "Full-wave rectifier", "RMS value of alternating voltage", "RMS value of rectified output voltage" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "$\\frac{V_0}{\\sqrt{2}}$", "B": "$\\frac{V_0^2}{\\sqrt{2}}$", "C": "$\\frac{2V_0}{\\sqrt{2}}$", "D": "$\\frac{V_0}{2\\sqrt{2}}$" }
null
false
null
null
null
null
74
(ii)
standard
In a full-wave rectifier, the current in each of the diodes flows for :
1
[ "Full-wave rectifier", "Diode operation" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "Complete cycle of the input signal", "B": "Half cycle of the input signal", "C": "Less than half cycle of the input signal", "D": "Only for the positive half cycle of the input signal" }
null
false
null
null
null
null
75
(iii)
standard
In a full-wave rectifier :
1
[ "Full-wave rectifier", "Diode biasing" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "Both diodes are forward biased at the same time.", "B": "Both diodes are reverse biased at the same time.", "C": "One is forward biased and the other is reverse biased at the same time.", "D": "Both are forward biased in the first half of the cycle and reverse biased in the second half of the cycle." }
null
false
null
null
null
null
76
(iv)
standard
An alternating voltage of frequency of 50 Hz is applied to a half-wave rectifier. Then the ripple frequency of the output will be :
1
[ "Half-wave rectifier", "Ripple frequency" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
null
null
{ "A": "100 Hz", "B": "50 Hz", "C": "25 Hz", "D": "150 Hz" }
null
false
null
null
null
null
77
b
standard
A signal, as shown in the figure, is applied to a p-n junction diode. Identify the output across resistance R₁:
1
[ "Semiconductor diode", "Rectifier" ]
Semiconductor Electronics: Materials, Devices and Simple Circuits
[ "img\\img_12.jpeg" ]
null
{ "A": "waveform with 10 V peak path: img\\img_13.jpeg", "B": "waveform with - 10 V peak path: Img\\img_14.jpeg", "C": "waveform with -path: Img\\img_15.jpeg", "D": "waveform with + 5 V peak path. img\\img_16.jpeg" }
null
false
null
null
null
null
78
30
standard
A lens is a transparent medium bounded by two surfaces, with one or both surfaces being spherical. The focal length of a lens is determined by the radii of curvature of its two surfaces and the refractive index of its medium with respect to that of the surrounding medium. The power of a lens is reciprocal of its focal length. If a number of lenses are kept in contact, the power of the combination is the algebraic sum of the powers of the individual lenses.
1
[ "Refraction of light", "Lenses", "Focal length", "Power of a lens", "Combination of lenses" ]
Ray Optics and Optical Instruments
null
null
null
null
false
null
null
null
null
79
(i)
standard
A double-convex lens, with each face having same radius of curvature R, is made of glass of refractive index n. Its power is :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Lens maker’s formula" ]
Ray Optics and Optical Instruments
null
null
{ "A": "$\\frac{2 (n - 1)}{R}$", "B": "$\\frac{(2n - 1)}{R}$", "C": "$\\frac{(n - 1)}{2R}$", "D": "$\\frac{(2n - 1)}{2R}$" }
null
false
null
null
null
null
80
(ii)
standard
A double-convex lens of power P, with each face having same radius of curvature, is cut into two equal parts perpendicular to its principal axis. The power of one part of the lens will be :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Combination of thin lenses in contact" ]
Ray Optics and Optical Instruments
null
null
{ "A": "2P", "B": "P", "C": "4P", "D": "$\\frac{P}{2}$" }
null
false
null
null
null
null
81
(iii)
standard
The above two parts are kept in contact with each other as shown in the figure. The power of the combination will be :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Combination of thin lenses in contact" ]
Ray Optics and Optical Instruments
[ "img\\img_17.jpeg" ]
null
{ "A": "$\\frac{P}{2}$", "B": "P", "C": "2P", "D": "$\\frac{P}{4}$" }
null
false
null
null
null
null
82
(iv)
standard
A double-convex lens of power P, with each face having same radius of curvature, is cut along its principal axis. The two parts are arranged as shown in the figure. The power of the combination will be :
1
[ "Refraction of light", "Lenses", "Power of a lens", "Combination of thin lenses in contact" ]
Ray Optics and Optical Instruments
[ "ing\\img_18.jpeg" ]
null
{ "A": "Zero", "B": "P", "C": "2P", "D": "$\\frac{P}{2}$" }
null
false
null
null
null
null
83
31.
standard
(a) (i) A ray of light passes through a triangular prism. Show graphically, how the angle of deviation varies with the angle of incidence ? Hence define the angle of minimum deviation.
5
[ "Refraction of light through a prism", "Angle of deviation", "Angle of minimum deviation" ]
Ray Optics and Optical Instruments
null
null
null
null
null
null
null
null
null
84
31.
standard
(a) (ii) A ray of light is incident normally on a refracting face of a prism of prism angle A and suffers a deviation of angle $\delta$. Prove that the refractive index n of the material of the prism is given by n=$ rac{\sin (A + \delta)}{\sin A}$.
5
[ "Refraction at plane surfaces", "Refractive index", "Prism formula" ]
Ray Optics and Optical Instruments
null
null
null
null
null
null
null
null
null
85
31.
standard
(a) (iii) The refractive index of the material of a prism is $\sqrt{2}$. If the refracting angle of the prism is $60^\circ$, find the
5
[ "Refraction of light through a prism", "Refractive index", "Angle of minimum deviation" ]
Ray Optics and Optical Instruments
null
null
null
null
null
null
null
null
null
86
31.
standard
(b) (i) State Huygens’ principle. A plane wave is incident at an angle i on a reflecting surface. Construct the corresponding reflected wavefront. Using this diagram, prove that the angle of reflection is equal to the angle of incidence.
5
[ "Huygens' principle", "Reflection of light", "Wavefront" ]
Wave Optics
null
null
null
null
null
null
null
null
null
87
31.
standard
(b) (ii) What are the coherent sources of light ? Can two independent sodium lamps act like coherent sources ? Explain.
5
[ "Coherent sources", "Interference" ]
Wave Optics
null
null
null
null
null
null
null
null
null
88
31.
standard
(b) (iii) A beam of light consisting of a known wavelength 520 nm and an unknown wavelength $\lambda$, used in Young's double slit experiment produces two interference patterns such that the fourth bright fringe of unknown wavelength coincides with the fifth bright fringe of known wavelength. Find the value of $\lambda$.
5
[ "Young's double slit experiment", "Interference", "Fringe width" ]
Wave Optics
null
null
null
null
null
null
null
null
null
89
32.
standard
(a) (i) Derive an expression for potential energy of an electric dipole $\vec{p}$ in an external uniform electric field $\vec{E}$. When is the potential energy of the dipole (1) maximum, and (2) minimum ? (ii) An electric dipole consists of point charges $-1.0$ pC and $+1.0$ pC located at (0, 0) and (3 mm, 4 mm) respectively in x – y plane. An electric field $\vec{E} = \left(\frac{1000 \text{V}}{\text{m}}\right) \hat{i}$ is switched on in the region. Find the torque $\vec{\tau}$ acting on the dipole.
5
[ "Electric potential energy of a dipole in an electrostatic field", "Torque on a dipole in uniform electric field" ]
Electrostatic Potential and Capacitance
null
null
null
null
false
null
null
null
null
90
33.
standard
(a) (i) A resistor and a capacitor are connected in series to an ac source $v = v_m \sin \omega t$. Derive an expression for the impedance of the circuit. (ii) When does an inductor act as a conductor in a circuit ? Give reason for it.
5
[ "Impedance of LCR series circuit", "Inductors in AC circuits" ]
Alternating Current
null
null
null
null
false
null
null
null
null
91
(iii)
standard
An electric lamp is designed to operate at 110 V dc and 11 A current. If the lamp is operated on 220 V, 50 Hz ac source with a coil in series, then find the inductance of the coil.
5
[ "Inductance", "AC Circuits", "Impedance" ]
Alternating Current
null
null
null
null
false
null
null
null
null
92
1
standard
A thin plastic rod is bent into a circular ring of radius R. It is uniformly charged with charge density Ξ». The magnitude of the electric field at its centre is :
0
[ "Electric field due to continuous charge distribution" ]
Electric Charges and Fields
null
null
{ "A": "$\\frac{\\lambda}{2\\varepsilon_0 R}$", "B": "Zero", "C": "$\\frac{\\lambda}{4\\pi\\varepsilon_0 R}$", "D": "$\\frac{\\lambda}{4\\varepsilon_0 R}$" }
null
false
null
null
null
null
93
2
standard
Three small charged spheres X, Y and Z carrying charges + q, βˆ’ q and + q respectively are placed equidistant from each other, as shown in the figure. The spheres Y and Z are held in place. Initially X is also held in place, but is otherwise free to move. When X is released, the path followed by it will be :
0
[ "Coulomb's law", "Force between multiple charges" ]
Electric Charges and Fields
[ "img\\img_19.jpeg" ]
null
{ "A": "A", "B": "B", "C": "C", "D": "D" }
null
false
null
null
null
null
94
3
standard
In a uniform straight wire, conduction electrons move along + x direction. Let $\vec{E}$ and $\vec{j}$ be the electric field and current density in the wire, respectively. Then :
0
[ "Drift velocity", "Electric current", "Current density" ]
Current Electricity
null
null
{ "A": "$\\vec{E}$ and $\\vec{j}$ both are along + x direction.", "B": "$\\vec{E}$ and $\\vec{j}$ both are along – x direction.", "C": "$\\vec{E}$ is along + x direction, but $\\vec{j}$ is along - x direction.", "D": "$\\vec{E}$ is along - x direction, but $\\vec{j}$ is along + x direction." }
null
false
null
null
null
null
95
4
standard
Two charged particles, P and Q, each having charge q but of masses $m_1$ and $m_2$, are accelerated through the same potential difference V. They enter a region of magnetic field $\vec{B}$ ($\vec{v} \perp \vec{B}$) and describe the circular paths of radii a and b respectively. Then $\left(\frac{m_1}{m_2}\right)$ is equal to :
0
[ "Motion in a magnetic field", "Kinetic energy and potential difference" ]
Moving Charges and Magnetism
null
null
{ "A": "$\\frac{a}{b}$", "B": "$\\frac{b}{a}$", "C": "$\\left(\\frac{a}{b}\\right)^2$", "D": "$\\left(\\frac{b}{a}\\right)^2$" }
null
false
null
null
null
null
96
5
standard
A galvanometer of resistance G Ξ© is converted into an ammeter of range 0 to I A. If the current through the galvanometer is 0.1% of I A, the resistance of the ammeter is :
1
[ "Moving Coil Galvanometer", "Conversion to Ammeter", "Shunt Resistance" ]
Moving Charges and Magnetism
null
null
{ "A": "$\\frac{G}{999} \\Omega$", "B": "$\\frac{G}{1000} \\Omega$", "C": "$\\frac{G}{1001} \\Omega$", "D": "$\\frac{G}{100-1} \\Omega$" }
null
false
null
null
null
null
97
6
standard
A 10 cm long wire lies along y-axis. It carries a current of 1.0 A in positive y-direction. A magnetic field $\vec{B} = (5 \text{ mT}) \hat{j} - (8 \text{ mT})\hat{k}$ exists in the region. The force on the wire is :
1
[ "Force on a current-carrying conductor in a magnetic field" ]
Moving Charges and Magnetism
null
null
{ "A": "$(0.8 \\text{ mN}) \\hat{i}$", "B": "$-(0.8 \\text{ mN}) \\hat{i}$", "C": "$(80 \\text{ mN}) \\hat{i}$", "D": "$-(80 \\text{ mN}) \\hat{i}$" }
null
false
null
null
null
null
98
7
standard
The primary and secondary coils of a transformer have 500 turns and 5000 turns respectively. The primary coil is connected to an ac source of 220 V – 50 Hz. The output across the secondary coil is :
1
[ "Transformer", "Turns Ratio", "Voltage Transformation" ]
Alternating Current
null
null
{ "A": "220 V – 50 Hz", "B": "1100 V – 50 Hz", "C": "2200 V – 5 Hz", "D": "2200 V – 50 Hz" }
null
false
null
null
null
null
99
8
standard
The first scientist who produced and observed electromagnetic waves of wavelengths in the range 25 mm – 5 mm was :
1
[ "Electromagnetic Waves", "Hertz's Experiment" ]
Electromagnetic Waves
null
null
{ "A": "J.C. Maxwell", "B": "H.R. Hertz", "C": "J.C. Bose", "D": "G. Marconi" }
null
false
null
null
null
null
100
9
standard
The waves associated with a moving electron and a moving proton have the same wavelength $\lambda$. It implies that they have the same :
1
[ "de-Broglie Wavelength", "Momentum and Wavelength" ]
Dual Nature of Radiation and Matter
null
null
{ "A": "momentum", "B": "angular momentum", "C": "speed", "D": "energy" }
null
false
null
null
null
null
End of preview. Expand in Data Studio

This data set contains the CBSE Class 12 2024 papers in a structured format. The papers are annotated with topic and chapter names, and the figures are parsed and their paths annotated.

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