GameChanger Academy

Mechanics

1. Units, Dimensions and Errors

2. Vectors and Scalars

3. Motion in a Straight Line

4. Projectile Motion

5. Newton's Laws of Motion

6. Friction

7. Work, Energy, Power and Collision

8. Circular motion

9. Rotational motion

10. Simple Harmonic Motion

11. Gravitation

12. Elasticity

13. Surface Tension

14. Fluid dynamics and Viscosity

15. Hydrostatics

Heat and Thermodynamics

16. Thermometry

17. Thermal expansion

18. Calorimetry, Change of State and Hygrometry

19. Gas Laws and Kinetic theory of Gases

20. Transmission of Heat

21. Thermodynamics

Sound and Waves

22. Wave

23. Superposition of Waves

24. Stationary/ Standing waves

25. Doppler's effect and Musical sound

Optics

26. Reflection of Plane and Curved Mirrors

27. Refraction at Plane surfaces and Total internal reflection

28. Refraction through prism and Dispersion of Light

29. Refraction through Lenses

30. Chromatic abberation in Lenses, Optical instruments and Human eye

31. Velocity of Light

32. Photometry

33. Wave nature of Light

Electrostatics

34. Charge and Force

35. Electric Field and Potential

36. Capacitance

Electrodynamics

37. Electric current

38. Heating Effect of Current

39. Thermoelectricity

40. Chemical effect of Current

41. Meters

Electromagnetism

42. Properties of Magnets

43. Magnetic effects of Current

44. Electromagnetic induction

45. Alternating current

Modern Physics

46. Cathode rays, Positive rays and Electrons

47. Photoelectric effect

48. X-rays

49. Atomic structure and Spectrum

50. Radioactivity

51. Nuclear physics

52. Semiconductor and Semiconductor devices

53. Diode and Triode valves

54. Logic gates

55. Relativity and Universe

56. Particle physics

Electromagnetism

43. Magnetic effects of Current

1. A proton is moving in the direction parallel to both electric and magnetic field, proton will [BP 2014]

get accelerated.
get decelerated..
move upward.
Move downward.

2. An electron enters X-direction and magnetic field is in Y-direction, The motion of electron after entering inside field is [BP 2014]

Circular motion in XY.
Circular motion in YZ.
Circular motion in XZ.
St. line.

3. A coil of metal wire is kept stationary in a non uniform magnetic field [BP 2014]

An emf and current both are induced in the coil.
An emf but not the current is induced in the coil.
Current but not emf is induce in the coil.
Neither emf nor current is induced in the coil.

4. Electric and magnetic field is in same directions and proton is also send in same direction then proton gets: [BP 2014]

Deviated to left.
Deviated to right.
Accelerated.
Deaccelerated.

5. A wire bent in the form of a square lamina of side 10 m in which a current I = 10 A circulates. The lamina is placed inside a magnetic field B = 10 tesla perpendicularly to the lamina surface. The force experienced by it is: [BP 2014]

1000 N
500 N
0 N
500 √3 N .

6. A length of wire carrying current when bent to form a circle magnetic field is B. If the same length is bent to form 'n' no. of circular loops, then magnetic field at centre is. [BP 2013]

n² B
nB
B/n
B

7. Uniform magnetic field has its direction from east to west, then direction of current due to motion of proton is directed towards: [BP 2012]

East
West
North
South

8. The magnetic field intensity at one end due to long current carrying solenoid is:

μ_o nI
(μ_o nI)/2
(μ_o I)/2
(μ_o nI)/2π

9. The radius of the path followed by a particle in a magnetic field directly proportional to its [BP 2011]

Charge
Magnetic
Momentum
Kinetic energy

10. A current is flowing north along a power line. The direction of the magnetic field above it, neglecting the earth's field is [BP 2011]

North
South
West
East.

11. Which of the following equation represents fourth Maxwell's law magnetic field above it, neglecting the earth's field is [BP 2011]

∫<0xE1><0xB5><0xB1>⋅d<0xE1><0xB5><0x83>=q/ε_o
∫B⋅d<0xE1><0xB5><0x83>=0
∫E⋅d<0xE1><0xB5><0x83>=−d/dt∫B⋅d<0xE1><0xB5><0x83>
∫B⋅d<0xE1><0xB5><0x83>=μ_o i+μ_o ε_o d/dt∫E⋅d<0xE1><0xB5><0x83>

12. Find the value of torque when the value of magnetic field is 0.2 tesla and magnetic moment is 2 amp m² acting perpendicular to each other [BP 2011]

13. When a charge moves , in a direction perpendicular to magnetic field then [BP 2010]

KE is constant and momentum changes.
Momentum is constant and KE changes
Both KE and momentum changes.
Both velocity and momentum are constant.

14. A toroid with 2000 turns and diameter of 40 cm has 2A current flowing through it. Then magnetic field at it's centre is [BP 2010]

1 x 10^-4 T
3 x 10^-4 T
2 x 10^-4 T
4 x 10^-4 T

15. Earth's magnetic field always has horizontal component except: [IOM]

at the equator
at a magnetic pole
at a latitude
at a longitude of 60°

16. A metallic wire is folded to form a square loop of side 'a'. It carries a current 'i' and is kept perpendicular to a uniform magnetic field. If the shape of the loop is changed from square to a circle without changing the length of the wire and current, the amount of work done in doing so is [BP 2009]

iBa² (π + 2)
iBa² (π-2)
iBa² (4/π - 1)
iBa² (1-4/π)

17. Two circular coils 1 and 2 are made from same wire but radius of 1st coil is twice that of 2nd coil. What potential difference should be applied across them so that the magnetic field at their centers is the same? [BP 2009]

18. The magnetic induction at a point 3 cm from a long current carrying wire is 10^-3 T. The field induction at 12 cm is [MOE 014]

10^-3 T
25 x 10^-4 T
2.5 x 10^-3 T
2.5 x 10^-4 T

19. When an electron moves through a uniform magnetic field, its speed [MOE 2013]

Increases
Decreases
Remains constant.
Depends on field.

20. An alpha particle of mass 6.65 x 10^-27 kg travels at right angle magnetic field of 0.2 T with a speed of 6 x10⁵ m/s. The acceleration the particle will be [MOE 2013].

5.77x 10¹² m/s²
5.77 x 10¹¹ m/s²
7.55 x 10¹² m/s²
7.55 x 10¹¹ m/s²

21. Two straight parallel conductors carrying current in opposite directions: [MOE 2013,12]

Attract each other .
Repel each other.
do not experience any force
cancel each other's force.

22. One meter wire carrying 2A is placed in magnetic fields 2 tesla force action on wire is [MOE 2012]

23. An electron travelling with a velocity 2 × 10⁵ m/s enters a magnetic field of 2 × 10^-5 T normal to velocity of electron, the radius of path the electron in magnetic field is. [MOE 2012]

0.2 cm
0.5 m
0.3 m
2 m

24. An electron enters in a magnetic field of 10^-3 T normally with velocity 10⁶ m/s. The radius of electron is : [MOE 2011]

11.4 cm
11.4 mm
5.7 cm
5.7 mm

25. An electron passing in direction east perpendicular to vertical magnetic field acting downwards. The deflection of the electron is towards: [MOE 2010]

South
East
West
North

26. A positively charged particles moving due east enters a region of uniform magnetic field directed vertically upwards. The particle will: [IOM 2013]

Move in a circular orbit with its speed increased.
Move in a circular orbit with its speed unchanged.
Move in a circular orbit with its speed unchanged
Continue to move due east.

27. When a rod of length 2m carrying current 10 A is placed perpendicular to magnetic flux density of strength of 0.15 T. What is the force experienced by it [IOM 2013]

2N
0.3 N
1 N
3 N

28. A current is flowing through a circular wire in clockwise direction. What will be the direction of magnetic lines of force:" [IOM 2013]

Parallel to the plane of the coil.
Perpendicular to the plane of the coil away from the reeader
Perpendicular to the plane of the coil towards the reader
At any angle

29. When a charged particle enters in strong magnetic field, its kinetic energy. [IOM 2011]

Increases
decreases
remain constant
first increases and becomes constant.

30. A long solenoid is formed by winding 20 turns/ cm. The current necessary to produce a magnetic field of 20 millitesla inside the solenoid will be approximately: [KU 2014]

1.0 A
2.0 A
4.0 A
8.0 A

31. A charged particle of mass m and charge q is moving with a velocity v in a magnetic field B. The work done by the magnetic field in moving the particle is given by [KU 2011]

Bqv
1/2 mv²
Bqv²
Zero

32. An electric current is flowing in a circular coil of radius 'a' at what distance from the centre on the axis of the coil will the magnetic field be 1/8th of its value at the centre.

√3 a
a
√2 a
2a

33. A long wire carries a current of 0.5 A. The flux density at a distance of 0.01 m is [Bangladesh Emb.]

2 x 10^-5 T
5 x 10^-5 T
10^-5 T
10^-7 T

34. An electron is moving in circular path in magnetic field intensity B then its time period is independent of [MOE 2056]

speed
mass
magnetic field
charge

35. Suppose we double the current flowing, the number of turns and the length of the coil of a long solenoid. If the original value of the magnetic field induction is B , then what is the value of the new magnetic field induction? [MOE 2053]

36. A coil of area 50 cm² is perpendicular to a uniform field of flux density 10^-3 Wm^-2. Then the flux passing through the coil is: [MOE 2062]

5 x 10^-5 weber
5 x 10^-6 weber
6 x 10^-6 weber
6 x 10^-6 weber

37. A magnetic needle is kept in a non-uniform magnetic field. It experiences [MOE 2062]

A force and a torque
A force but not a torque
A torque but not a force
Neither a force nor a torque

38. An electron enters in magnetic field with velocity 2x10⁶ ms^-1 perpendicular to the field of 2x10^-5 T. What is the radius of the path of electron? [MOE 2065]

0.57m
7.5m
2.4m
0.24m

39. Energy stored in magnetic field of 2.5 x10^-3T is [IE-05]

2.48J/m^3
2.48×10^-9 J/m^3
3.48 J
4.48 J

40. If the rectangular coil is set with plane of symmetry along z-axis in a parallel magnetic field then torque experienced by coil is [IE-05]

BINA
zero
BAN
BIL

41. When an electric beam is shot horizontally in an electric field and perpendicular to a magnetic field, the beam follows: [BPKIHS-94]

Circular paths in both fields
Circular path in electric and parabolic in magnetic field.
Parabolic paths in both fields
Parabolic path in electric and circular in magnetic field

42. A wire of length l carries a steady current. It is about first to form a circular plane loop of one turn. The magnetic field at the center of. The same length is now bent more sharply to give a double loop of smaller radius. The magnetic field at the center caused by the same is: [BPKIHS-08]

43. A charged particle enters a magnetic field at right angles to the magnetic field. The field exist for a length equal to 1.5 times the radius of the circular path of the particle. The particle will be deviated from its path by. [BPKIHS-09]

90°
sin⁻¹(2/3)
30°
180°

44. An electron enters a region where magnetic (B) and electric (E) fields are mutually perpendicular. Then, [BPKIHS 01]

It will always move in the direction of B
It will always move in the direction of E
It always possesses circular motion
It can go undeflected also

45. An electric charge q moves with a constant velocity v parallel to the lines of force of a uniform magnetic field B. The force experienced by the charge is [MOE 2010]

q vB
qv/B
Bv/q
zero

46. Two thin long parallel wires separated by a distance 'b' are carrying a current'i' ampere each. The magnitude of the force per unit length exerted by one wire on the other is: [IOM 08]

(μ_o i²)/b²
(μ_o i²)/2πb
(μ_o i)/2πb
(μ_o i)/2πb

47. A charge of 2 coulombs moving with velocity 0.5 m/s at an angle of 30° with the field of 4 T experiences force of: [IOM 07]

1 N
2 N
4N
1/4 N

48. If a wire carrying current "I" is bent to two arms making right angle, between them then the magnetic field intensity 'B' at the distance "a" from both arms is: [IOM 03]

(μ_o I)/4πa
(μ_o I)/2a
(μ_o I)/(√2 2πa)
(μ_o I)/2(a+√a)

49. A solenoid of length 20 cm and diameter 2 cm has 4250 turns. If a current of 2A is flowing through it, what is the magnetic field at the center of the solenoid? [MOE 066]

5.3 x 10^-2 Web/m²
2.3x10² Web/m²
6.3 x 10² Web/m²
10.3x10² Web/m²

50. An electron is moving with a velocity v and enters a uniform electric field perpendicularly. Its trajectory within the field will be [MOE 2009]

Parabolic
Circular
Hyperbolic
Elliptic

51. A charged particle enters in a magnetic field perpendicular to the magnetic lines of force. The path of particles is [Bangladesh 09]

Straight line
Circular
Ellipse
Spiral

52. The net force on a magnetic dipole in a uniform magnetic field: [IE-07]

towards north pole
towards sound pole
zero
not enough information given

53. Magnetic field invariably contain: [[E-07]

a ferromagnetic material
inductance
electric current
energy

54. Magnetic field do not interact with [IE-08]

Stationary electric charge
Moving electric charge
Stationary permanent magnet
Moving permanent magnet

55. An electron of mass = 9x10^-31 kg, charge =1.6 × 10^-19 C moving with a velocity of 10⁶ m/s enters a region where magnetic field exists. It is described on a circle of radius 0.1m, the strength of magnetic field must be: [TE-08]

1.8 × 10^-4 T.
5.6 × 10^-5 T
14.4×10^-1 T
1.4×10^-6 T

56. A particle ' is projected in a plane perpendicular to uniform magnetic field. The path described by the particle is proportional to [BPKIHS-95]

The velocity
The momentum
The kinetic energy
None of the above

57. An electron is moving in a region where both electric and magnetic fields are present. It will gain energy from

Magnetic
Electric
Both fields
Neither field

58. A straight wire lies along X-axis from x=−a/2 to x=+a/2 and carries a steady current I. The magnetic field due to the wire at a point x = + a will be

∝a
∝a²
∝1/a
equal to zero

59. Two circular coils are made of two identical wires of same length. If the number of turns of two coils is 4 and 2, then the ratio of magnetic induction at centres coil will be

60. A proton moving in a perpendicular magnetic field B possesses energy E. If the magnetic field increases to 4B and the particle is constrained to move in the path of same radius, the kinetic energy of proton must be

increased to 4 times
increased to 16 times
reduced to half
unchanged

61. If two streams of protons move parallel to each other in the same direction, then these

do not interact at all
attract each other
repel each other
deflect perpendicular to the plane of streams

62. A wire having length l and carrying current I is bent in circular form. Then find the dipole moment of circular coil

(Il²)/4π
(Il²)/2π
4π² l² I
π² l² I

63. A uniform electric field and a uniform magnetic field are produced, pointed in the same direction. An electron is projected with its velocity pointed in same direction. The electron velocity will

increase
decrease
change in direction
not change

64. A strong magnetic field is applied on a stationary electron, then the electron

moves in direction of field
moves in an opposite direction of field
remains stationary
starts opening

65. Two particles X and Y having equal charges after being accelerated through the same p.d. enter a region of uniform magnetic field and describe circular paths of radii R₁, and R₂, respectively. The ratio of mass of X to that of Y is

√(R₁/R₂ )
R₂/R₁
(R₁/R₂ )²
R₁/R₂

66. If proton and α-particle moving with same energy enter normally in a uniform magnetic field then the ratio of their radii and time period will be

1:1 and 1:2
1:2 and 1:1
1:2 and 2:1
2:1 and 2:1

67. An electron accelerated through a potential of V volt enter normally in a uniform magnetic field and experiences force. F. If potential is doubled then force experienced by the electron will be.

√2 F
F/√2
F
none

68. Three charged particles H⁺, He⁺ and O⁺⁺ moving with same energy enter normally in uniform magnetic field then

H⁺ deflects most
H⁺ and He⁺ deflect equally
He⁺ deflects least
All deflect equally

69. An electron and a proton having same kinetic energy enter a magnetic field perpendicularly. Which of the following is true?

Trajectory of electron is less curved
Trajectory of proton is less curved
Both the trajectories are equally curved.
Both move on straight line path

70. Two circular coils having their current of radius ratio 1:1 are kept normal to each other with their common centres. Then the magnetic field at their common centre is

μ_o √2
μ_o
2μ_o
μ_o/√2

71. Two circular coils P and Q are made of same wire but radius of Q is twice that of P. Then find the ratio of p.d across them so that magnetic field at their centres is equal

72. A square carrying current I and having side length l. Then find the magnetic field at the centre

(2√2 μ_o I)/πl
(√2 μ_o I)/πl
(μ_o I)/πl
(4μ_o I)/πl

73. Find the magnetic field at point O shown in figure

(μ_o I)/4r
(μ_o I)/2r
(μ_o I)/4r+(μ_o I)/2πr
(μ_o I)/2πr

74. Ratio of magnetic field induction at the centre of a current carrying coil of radius R and at a distance 3R on its axis is

√10
2√10
20√10
10√10

75. A long, straight, solid metal wire of radius 2mm carries a current uniformly distributed over its circular cross section. The magnetic field induction at a distance 2mm from its axis is B. Then the magnetic field induction at distance 1 mm from the axis will be

76. Two straight long wires are set parallel to each other with a distance of 2r between them. If each wire carries a current I in the same direction, the strength of magnetic field at a distance r between the two wires is

μ₀I/4πr
μ₀I/πr
μ₀I/2πr
zero

77. If a long copper current the magnetic field associated with the current will be

only inside the rod
only outside the rod
both inside and outside the rod
neither inside nor outside the rod

78. At the midpoint along the length of a long solenoid, the magnetic field is equal to B. If the length of solenoid is doubled and the current is reduced to half, the magnetic field at the new mid-point will nearest to

79. The frequency of charged particle, moving at right angle to the magnetic field is independent of

the radius of circular trajectory
the speed of particle
both 'a' and 'b'
the magnetic induction B.

80. An electric field of 1500 volt/meter and magnetic field of 0.40 Weber/m2 act on a moving electron to produce no force. What is the electron speed?

600 m/s
1/600 m/s
3750 m/s.
1/3750 m/s

81. A proton and α-particle enter a uniform magnetic field perpendicular with the same speed. If proton takes 20μ second to make 5 revolutions, then the periodic time for the α-particle would be

5μ sec
8μ sec
10μ sec
16μ sec

82. A circular loop area 0.02m2 carrying a current of 10A is held with its plane perpendicular to a magnetic field induction 0.2T. The torque acting on the loop is

0.01Nm
0.001Nm
zero
0.8Nm

83. Through two parallel wires A and B, 10A and 2A of current are passed respectively in opposite directions. If the wire A is infinitely long and the length of the wire B is 2m, then force on the conductor B which is situated at 10cm distance from A, will be

8 × 10^-7 N
8 × 10^-5 N
4 × 10^-7 N
4 × 10^-5 N

84. Two identical co-axial circular loops carry a current I each circulating in the same direction. If the loops approach each other, then current in each loop.

remains the same
increases
decreases
becomes zero

85. Two parallel long wires A. and B carry currents, I1 and I2 (

86. An electron of charge e moves with a constant speed v along a circle of radius r. Its magnetic moment will be

evr/2
evr
πr^2 ev
2πrev

87. A current carrying rectangular coil is placed in a uniform magnetic field. In which orientation, the coil will tend to rotate?

The magnetic field is parallel to the plane of the coil
The magnetic field is perpendicular to the plane of coil
The magnetic field is at 45° with the plane of the coil
Always in any orientations

88. An alpha particle is accelerated through a p.d. of 10⁶ volt. Its K.E will be

1 Mev
2 MeV
5 MeV
8 MeV.

89. The magnetic moment of a circular coil carrying current is

directly proportional to the length of the wire in the coil
inversely proportional to the length of the wire in the coil
directly proportional to the square of the length of the wire in the coil
inversely proportional to the square of the length of the wire in the coil.

90. A long solenoid has 200 turns per cm and carries a current of 2.5 amp. The magnetic field at its centre is. (μo = 4πx10^-7 weber/m²] IKU 2014

3.14×10⁻¹² Wb/m²
9.42×10⁻² Wb/m²
12.56×10⁻² Wb/m²
6.28×10⁻² Wb/m²

91. Force per unit length at one end of each of the two parallel wires, carrying current I each, kept distance r apart is

(μ_o I²)/4πr
(μ_o (2I)²)/4πr
(μ_o (2I)²)/4πr
(μ_o I²)/4π4r

92. A particle of charge q and mass m moves in a circular orbit of radius r with angular speed ω. The ratio of the magnitude of its magnetic moment to that of its angular momentum depends on

ω and q
ωq and m
q and m
Ω and m

93. Two wires of same length are shaped into a square and a circle. If they carry same current, ratio of the magnetic moments is

π:4
π:2
2:π
4:π

94. A wire is wound in the form of a solenoid of length / and diameter d. When a strong current is passed through the solenoid there is tendency to

keep both l and d constant
decrease both l and d
increase both l and d
decrease l and increase d

95. An electron moves in a circular orbit with a uniform speed v. It produces a magnetic field B at the centre of the circle. The radius of the circle is proportional to

√(v/B)
v/B
B/v
B/v²

96. A helium nucleus makes a full rotation in a circle of radius 0.8 metre in 2sec. . The value of the magnetic field induction B in tesla at the centre of circle will be [BP 2012, MOE 2011]

10⁻¹⁹ μ_o
2×10⁻¹⁹ μ_o
10⁻¹⁹/μ_o
(2×10⁻²⁰)/μ_o

97. A uniform wire in bent in the form of a circle of radius R.A current I enters at A and leaves at C as shown in figure. If the C is half of the length ADC, the magnetic field at the centre O will be

Zero
(μ_o I²)/2πR
(μ_o I)/4R
(μ_o I)/2R

98. An electron moving upwards vertically enters a uniform magnetic field directed towards north. The force on the electron will be towards

- north
East
West
south

99. The mass of a proton is 1847 times that of electron. If an electron and a proton are injected in a uniform electric field at right angle to the direction of the field, with the same kinetic energy, then.

the trajectory of the proton will be less curved than that of electron
the trajectory of the electron will be less curved than that of proton
both the trajectories will be straight
both the trajectories will be equally curved.

100. When the magnetic field is applied across the north & the positive charge is deflected toward the east then current flowing is: [KU 2016]

East
West
Downward
Upward